Transmission method and reception device

ABSTRACT

The present technology relates to a transmission method and a reception device capable of ensuring good communication quality in data transmission by using an LDPC code. In group-wise interleaving, an LDPC code with a code length N of 69120 bits is interleaved in units of bit groups of 360 bits. In group-wise deinterleaving, an arrangement of the LDPC code after the group-wise interleaving is returned to an original arrangement. The present technology can be applied, for example, to the case of performing data transmission by using an LDPC code or the like.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a U.S. National Phase of International Patent Application No. PCT/JP2018/003900 filed on Feb. 6, 2018, which claims priority benefit of Japanese Patent Application No. JP 2017-056766 filed in the Japan Patent Office on Mar. 23, 2017 and also claims priority benefit of Japanese Patent Application No. JP 2017-028567 filed in the Japan Patent Office on Feb. 20, 2017. Each of the above-referenced applications is hereby incorporated herein by reference in its entirety.

TECHNICAL FIELD

The present technology relates to a transmission method and a reception device, and more particularly, to a transmission method and a reception device that can ensure good communication quality, for example, in data transmission using an LDPC code.

BACKGROUND ART

Low density parity check (LDPC) codes have high error correction capability, and in recent years, have been widely adopted in transmission schemes such as digital broadcasting, for example, digital video broadcasting (DVB)-S.2, or DVB-T.2, DVB-C.2, in Europe or the like or advanced television systems committee (ATSC) 3.0 or the like in the United States or the like (refer to, for example, Non-Patent Document 1).

With recent researches, it has been found that, similarly to turbo codes and the like, in LDPC codes, performance close to the Shannon limit is obtained as the code length is increased. In addition, since the LDPC code has the property that the minimum distance is proportional to the code length, features that a block error probability characteristic is good and so-called error floor phenomenon observed in a decoding characteristic of turbo code or the like hardly occurs are also mentioned as an advantage.

CITATION LIST Non-Patent Document

-   Non-Patent Document 1: ATSC Standard: Physical Layer Protocol     (A/322), 7 Sep. 2016

SUMMARY OF THE INVENTION Problems to be Solved by the Invention

In data transmission using an LDPC code, for example, the LDPC code becomes a symbol of quadrature modulation (digital modulation) such as quadrature phase shift keying (QPSK) (that is, the LDPC code is symbolized), and the symbol is mapped to a signal point of the quadrature modulation to be transmitted.

The data transmission using the LDPC code as described above has been spread in the worldwide, and it is required to ensure good communication (transmission) quality.

The present technology has been made in view of such a circumstance and is to ensure good communication quality in data transmission using an LDPC code.

Solutions to Problems

A first transmission method according to the present technology is a transmission method including: an encoding step of performing LDPC encoding on the basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 3/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in which in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

138, 38, 106, 76, 172, 27, 150, 95, 44, 187, 64, 18, 28, 98, 180, 101, 149, 146, 126, 26, 93, 178, 186, 70, 104, 131, 19, 45, 102, 122, 152, 66, 63, 173, 9, 55, 25, 1, 154, 85, 5, 51, 43, 82, 86, 151, 148, 48, 190, 179, 62, 60, 94, 174, 142, 39, 169, 170, 47, 125, 33, 128, 162, 2, 129, 57, 79, 118, 114, 69, 78, 167, 11, 136, 99, 155, 90, 21, 119, 10, 52, 91, 115, 185, 6, 110, 88, 96, 181, 143, 0, 160, 124, 130, 183, 71, 121, 182, 68, 191, 3, 32, 40, 189, 41, 156, 35, 159, 58, 89, 29, 67, 17, 109, 30, 111, 12, 46, 65, 177, 53, 77, 74, 56, 184, 15, 141, 135, 54, 163, 14, 145, 139, 134, 59, 147, 87, 107, 7, 61, 36, 113, 103, 188, 24, 165, 137, 22, 42, 49, 83, 73, 50, 161, 20, 166, 127, 157, 108, 171, 37, 72, 176, 112, 123, 144, 34, 175, 168, 117, 80, 81, 8, 31, 133, 92, 164, 132, 97, 158, 84, 100, 140, 16, 105, 23, 75, 13, 153, 116, 4, 120,

the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is

126 1125 1373 4698 5254 17832 23701 31126 33867 46596 46794 48392 49352 51151 52100 55162

794 1435 1552 4483 14668 16919 21871 36755 42132 43323 46650 47676 50412 53484 54886 55333

698 1356 1519 5555 6877 8407 8414 14248 17811 22998 28378 40695 46542 52817 53284 55968

457 493 1080 2261 4637 5314 9670 11171 12679 29201 35980 43792 44337 47131 49880 55301

467 721 1484 5326 8676 11727 15221 17477 21390 22224 27074 28845 37670 38917 40996 43851

305 389 526 9156 11091 12367 13337 14299 22072 25367 29827 30710 37688 44321 48351 54663

23 342 1426 5889 7362 8213 8512 10655 14549 15486 26010 30403 32196 36341 37705 45137

123 429 485 4093 6933 11291 11639 12558 20096 22292 24696 32438 34615 38061 40659 51577

920 1086 1257 8839 10010 13126 14367 18612 23252 23777 32883 32982 35684 40534 53318 55947

579 937 1593 2549 12702 17659 19393 20047 25145 27792 30322 33311 39737 42052 50294 53363

116 883 1067 9847 10660 12052 18157 20519 21191 24139 27132 27643 30745 33852 37692 37724

915 1154 1698 5197 5249 13741 25043 29802 31354 32707 33804 36856 39887 41245 42065 50240

317 1304 1770 12854 14018 14061 16657 24029 24408 34493 35322 35755 38593 47428 53811 55008

163 216 719 5541 13996 18754 19287 24293 38575 39520 43058 43395 45390 46665 50706 55269

42 415 1326 2553 7963 14878 17850 21757 22166 32986 39076 39267 46154 46790 52877 53780

593 1511 1515 13942 14258 14432 24537 38229 38251 40975 41350 43490 44880 45278 46574 51442

219 262 955 1978 10654 13021 16873 23340 27412 32762 40024 42723 45976 46603 47761 54095

632 944 1598 12924 17942 18478 26487 28036 42462 43513 44487 44584 48245 53274 54343 55453

501 912 1656 2009 6339 15581 20597 26886 32241 34471 37497 43009 45977 46587 46821 51187

610 713 1619 5176 6122 6445 8044 12220 14126 32911 38647 40715 45111 47872 50111 55027

258 445 1137 4517 5846 7644 15604 16606 16969 17622 20691 34589 35808 43692 45126 49527

612 854 1521 13045 14525 15821 21096 23774 24274 25855 26266 27296 30033 40847 44681 46072

714 876 1365 5836 10004 15778 17044 22417 26397 31508 32354 37917 42049 50828 50947 54052

1338 1595 1718 4722 4981 12275 13632 15276 15547 17668 21645 26616 29044 39417 39669 53539

687 721 1054 5918 10421 13356 15941 17657 20704 21564 23649 35798 36475 46109 46414 49845

734 1635 1666 9737 23679 24394 24784 26917 27334 28772 29454 35246 35512 37169 39638 44309

469 918 1212 3912 10712 13084 13906 14000 16602 18040 18697 25940 30677 44811 50590 52018

70 332 496 6421 19082 19665 25460 27377 27378 31086 36629 37104 37236 37771 38622 40678

48 142 1668 2102 3421 10462 13086 13671 24889 36914 37586 40166 42935 49052 49205 52170

294 616 840 2360 5386 7278 10202 15133 24149 24629 27338 28672 31892 39559 50438 50453

517 946 1043 2563 3416 6620 8572 10920 31906 32685 36852 40521 46898 48369 48700 49210

1325 1424 1741 11692 11761 19152 19732 28863 30563 34985 42394 44802 49339 54524 55731

664 1340 1437 9442 10378 12176 18760 19872 21648 34682 37784 40545 44808 47558 53061

378 705 1356 16007 16336 19543 21682 28716 30262 34500 40335 44238 48274 50341 52887

999 1202 1328 10688 11514 11724 15674 21039 35182 36272 41441 42542 52517 54945 56157

247 384 1270 6610 10335 24421 25984 27761 38728 41010 46216 46892 47392 48394 51471

10091 10124 12187 13741 18018 20438 21412 24163 35862 36925 37532 46234 7860 8123 8712 17553 20624 29410 29697 29853 43483 43603 53476 53737 11547 11741 19045 20400 23052 28251 32038 44283 50596 53622 55875 55888 3825 11292 11723 13819 26483 28571 33319 33721 34911 37766 47843 48667 10114 10336 14710 15586 19531 22471 27945 28397 45637 46131 47760 52375.

A first reception device according to the present technology is a reception device including a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, in which the transmission device includes: an encoding unit that performs LDPC encoding on the basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 3/16, a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

138, 38, 106, 76, 172, 27, 150, 95, 44, 187, 64, 18, 28, 98, 180, 101, 149, 146, 126, 26, 93, 178, 186, 70, 104, 131, 19, 45, 102, 122, 152, 66, 63, 173, 9, 55, 25, 1, 154, 85, 5, 51, 43, 82, 86, 151, 148, 48, 190, 179, 62, 60, 94, 174, 142, 39, 169, 170, 47, 125, 33, 128, 162, 2, 129, 57, 79, 118, 114, 69, 78, 167, 11, 136, 99, 155, 90, 21, 119, 10, 52, 91, 115, 185, 6, 110, 88, 96, 181, 143, 0, 160, 124, 130, 183, 71, 121, 182, 68, 191, 3, 32, 40, 189, 41, 156, 35, 159, 58, 89, 29, 67, 17, 109, 30, 111, 12, 46, 65, 177, 53, 77, 74, 56, 184, 15, 141, 135, 54, 163, 14, 145, 139, 134, 59, 147, 87, 107, 7, 61, 36, 113, 103, 188, 24, 165, 137, 22, 42, 49, 83, 73, 50, 161, 20, 166, 127, 157, 108, 171, 37, 72, 176, 112, 123, 144, 34, 175, 168, 117, 80, 81, 8, 31, 133, 92, 164, 132, 97, 158, 84, 100, 140, 16, 105, 23, 75, 13, 153, 116, 4, 120,

the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is

126 1125 1373 4698 5254 17832 23701 31126 33867 46596 46794 48392 49352 51151 52100 55162

794 1435 1552 4483 14668 16919 21871 36755 42132 43323 46650 47676 50412 53484 54886 55333

698 1356 1519 5555 6877 8407 8414 14248 17811 22998 28378 40695 46542 52817 53284 55968

457 493 1080 2261 4637 5314 9670 11171 12679 29201 35980 43792 44337 47131 49880 55301

467 721 1484 5326 8676 11727 15221 17477 21390 22224 27074 28845 37670 38917 40996 43851

305 389 526 9156 11091 12367 13337 14299 22072 25367 29827 30710 37688 44321 48351 54663

23 342 1426 5889 7362 8213 8512 10655 14549 15486 26010 30403 32196 36341 37705 45137

123 429 485 4093 6933 11291 11639 12558 20096 22292 24696 32438 34615 38061 40659 51577

920 1086 1257 8839 10010 13126 14367 18612 23252 23777 32883 32982 35684 40534 53318 55947

579 937 1593 2549 12702 17659 19393 20047 25145 27792 30322 33311 39737 42052 50294 53363

116 883 1067 9847 10660 12052 18157 20519 21191 24139 27132 27643 30745 33852 37692 37724

915 1154 1698 5197 5249 13741 25043 29802 31354 32707 33804 36856 39887 41245 42065 50240

317 1304 1770 12854 14018 14061 16657 24029 24408 34493 35322 35755 38593 47428 53811 55008

163 216 719 5541 13996 18754 19287 24293 38575 39520 43058 43395 45390 46665 50706 55269

42 415 1326 2553 7963 14878 17850 21757 22166 32986 39076 39267 46154 46790 52877 53780

593 1511 1515 13942 14258 14432 24537 38229 38251 40975 41350 43490 44880 45278 46574 51442

219 262 955 1978 10654 13021 16873 23340 27412 32762 40024 42723 45976 46603 47761 54095

632 944 1598 12924 17942 18478 26487 28036 42462 43513 44487 44584 48245 53274 54343 55453

501 912 1656 2009 6339 15581 20597 26886 32241 34471 37497 43009 45977 46587 46821 51187

610 713 1619 5176 6122 6445 8044 12220 14126 32911 38647 40715 45111 47872 50111 55027

258 445 1137 4517 5846 7644 15604 16606 16969 17622 20691 34589 35808 43692 45126 49527

612 854 1521 13045 14525 15821 21096 23774 24274 25855 26266 27296 30033 40847 44681 46072

714 876 1365 5836 10004 15778 17044 22417 26397 31508 32354 37917 42049 50828 50947 54052

1338 1595 1718 4722 4981 12275 13632 15276 15547 17668 21645 26616 29044 39417 39669 53539

687 721 1054 5918 10421 13356 15941 17657 20704 21564 23649 35798 36475 46109 46414 49845

734 1635 1666 9737 23679 24394 24784 26917 27334 28772 29454 35246 35512 37169 39638 44309

469 918 1212 3912 10712 13084 13906 14000 16602 18040 18697 25940 30677 44811 50590 52018

70 332 496 6421 19082 19665 25460 27377 27378 31086 36629 37104 37236 37771 38622 40678

48 142 1668 2102 3421 10462 13086 13671 24889 36914 37586 40166 42935 49052 49205 52170

294 616 840 2360 5386 7278 10202 15133 24149 24629 27338 28672 31892 39559 50438 50453

517 946 1043 2563 3416 6620 8572 10920 31906 32685 36852 40521 46898 48369 48700 49210

1325 1424 1741 11692 11761 19152 19732 28863 30563 34985 42394 44802 49339 54524 55731

664 1340 1437 9442 10378 12176 18760 19872 21648 34682 37784 40545 44808 47558 53061

378 705 1356 16007 16336 19543 21682 28716 30262 34500 40335 44238 48274 50341 52887

999 1202 1328 10688 11514 11724 15674 21039 35182 36272 41441 42542 52517 54945 56157

247 384 1270 6610 10335 24421 25984 27761 38728 41010 46216 46892 47392 48394 51471

10091 10124 12187 13741 18018 20438 21412 24163 35862 36925 37532 46234 7860 8123 8712 17553 20624 29410 29697 29853 43483 43603 53476 53737 11547 11741 19045 20400 23052 28251 32038 44283 50596 53622 55875 55888 3825 11292 11723 13819 26483 28571 33319 33721 34911 37766 47843 48667 10114 10336 14710 15586 19531 22471 27945 28397 45637 46131 47760 52375.

A second transmission method according to the present technology is a transmission method including: an encoding step of performing LDPC encoding on the basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 5/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in which in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

37, 136, 161, 62, 163, 129, 160, 73, 76, 66, 34, 162, 122, 5, 87, 94, 50, 105, 132, 32, 121, 47, 74, 189, 110, 45, 75, 175, 17, 29, 108, 191, 1, 153, 20, 113, 61, 42, 51, 2, 165, 124, 43, 186, 40, 86, 168, 180, 155, 16, 93, 26, 166, 119, 159, 56, 12, 44, 46, 143, 49, 25, 176, 158, 92, 147, 54, 172, 182, 64, 157, 112, 38, 39, 11, 6, 127, 48, 151, 82, 4, 36, 183, 88, 126, 117, 111, 188, 138, 65, 70, 170, 133, 137, 146, 128, 114, 148, 141, 125, 10, 41, 116, 33, 99, 81, 187, 130, 131, 107, 60, 90, 173, 13, 71, 15, 106, 3, 149, 154, 181, 174, 190, 27, 177, 18, 21, 22, 83, 91, 150, 14, 96, 53, 0, 145, 67, 68, 144, 184, 59, 23, 118, 115, 135, 55, 134, 102, 8, 169, 85, 156, 97, 63, 104, 95, 52, 98, 139, 24, 78, 179, 19, 28, 69, 58, 109, 57, 164, 31, 84, 140, 103, 77, 123, 171, 72, 79, 152, 35, 80, 7, 185, 167, 9, 100, 142, 89, 30, 120, 178, 101,

the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is

152 1634 7484 23081 24142 26799 33620 40989 41902 44319 44378 45067 140 701 5137 7313 12672 16929 20359 27052 30236 33846 36254 46973 748 769 2891 7812 9964 15629 19104 20551 25796 28144 31518 34124 542 976 2279 18904 20877 24190 25903 28129 36804 41152 41957 46888 173 960 2926 11682 12304 13284 18037 22702 30255 33718 34073 37152 78 1487 4898 7472 8033 10631 11732 19334 24577 34586 38651 43639 594 1095 1857 2368 8909 17295 17546 21865 23257 31273 37013 41454 72 419 1596 7849 16093 23167 26923 31883 36092 40348 44500 866 1120 1568 1986 3532 20094 21663 26664 26970 33542 42578 868 917 1216 12018 15402 20691 24736 33133 36692 40276 46616 955 1070 1749 7988 10235 19174 22733 24283 27985 38200 44029 613 1729 1787 19542 21227 21376 31057 36104 36874 38078 42445 86 1555 1644 4633 14402 14997 25724 31382 31911 32224 43900 353 1132 1246 5544 7248 17887 25769 27008 28773 33188 44663 600 958 1376 6417 6814 17587 20680 25376 29522 31396 40526 179 528 1472 2481 5589 15696 20148 28040 29690 32370 42163 122 144 681 6613 11230 20862 26396 27737 35928 39396 42713 934 1256 1420 3881 4487 5830 7897 9587 17940 40333 41925 622 1458 1490 16541 18443 19401 24860 26981 28157 32875 38755 1017 1143 1511 2169 17322 24662 25971 29149 31450 31670 34779 935 1084 1534 2918 10596 11534 17476 27269 30344 31104 37975 173 532 1766 8001 10483 17002 19002 26759 31006 43466 47443 221 610 1795 9197 11770 12793 14875 30177 30610 42274 43888 188 439 1332 7030 9246 15150 26060 26541 27190 28259 36763 812 1643 1750 7446 7888 7995 18804 21646 28995 30727 39065 44 481 555 5618 9621 9873 19182 22059 42510 45343 46058 156 532 1799 6258 18733 19988 23237 27657 30835 34738 39503 1128 1553 1790 8372 11543 13764 17062 28627 38502 40796 42461 564 777 1286 3446 5566 12105 16038 18918 21802 25954 28137 1167 1178 1770 4151 11422 11833 16823 17799 19188 22517 29979 576 638 1364 12257 22028 24243 24297 31788 36398 38409 47211 334 592 940 2865 12075 12708 21452 31961 32150 35723 46278 1205 1267 1721 9293 18685 18917 23490 27678 37645 40114 45733 189 628 821 17066 19218 21462 25452 26858 38408 38941 42354 190 951 1019 5572 7135 15647 32613 33863 33981 35670 43727 84 1003 1597 12597 15567 21221 21891 23151 23964 24816 46178 756 1262 1345 6694 6893 9300 9497 17950 19082 35668 38447 848 948 1560 6591 12529 12535 20567 23882 34481 46531 46541 504 631 777 10585 12330 13822 15388 23332 27688 35955 38051 676 1484 1575 2215 5830 6049 13558 25034 33602 35663 41025 1298 1427 1732 13930 15611 19462 20975 23200 30460 30682 34883 1491 1593 1615 4289 7010 10264 21047 26704 27024 29658 46766 969 1730 1748 2217 7181 7623 15860 21332 28133 28998 36077 302 1216 1374 5177 6849 7239 10255 34952 37908 39911 41738 220 362 1491 5235 5439 22708 29228 29481 33272 36831 46487 4 728 1279 4579 8325 8505 27604 31437 33574 41716 45082 472 735 1558 4454 6957 14867 18307 22437 38304 42054 45307 85 466 851 3669 7119 32748 32845 41914 42595 42600 45101 52 553 824 2994 4569 12505 24738 33258 37121 43381 44753 37 495 1553 7684 8908 12412 15563 16461 17872 29292 30619 254 1057 1481 9971 18408 19815 28569 29164 39281 42723 45604 16 1213 1614 4352 8091 8847 10022 24394 35661 43800 44362 395 750 888 2582 3772 4151 26025 36367 42326 42673 47393 862 1379 1441 6413 25621 28378 34869 35491 41774 44165 45411 46 213 1597 2771 4694 4923 17101 17212 19347 22002 43226 1339 1544 1610 13522 14840 15355 29399 30125 33685 36350 37672 251 1162 1260 9766 13137 34769 36646 43313 43736 43828 45151 214 1002 1688 5357 19091 19213 24460 28843 32869 35013 39791 646 733 1735 11175 11336 12043 22962 33892 35646 37116 38655 293 927 1064 4818 5842 10983 12871 17804 33127 41604 46588 10927 15514 22748 34850 37645 40669 41583 44090 3329 7548 8092 11659 16832 35304 46738 46888 3510 5915 9603 30333 37198 42866 44361 46416 2575 5311 9421 13410 15375 34017 37136 43990 12468 14492 24417 26394 38565 38936 41899 45593.

A second reception device according to the present technology is a reception device including a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, in which the transmission device includes: an encoding unit that performs LDPC encoding on the basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 5/16; a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

37, 136, 161, 62, 163, 129, 160, 73, 76, 66, 34, 162, 122, 5, 87, 94, 50, 105, 132, 32, 121, 47, 74, 189, 110, 45, 75, 175, 17, 29, 108, 191, 1, 153, 20, 113, 61, 42, 51, 2, 165, 124, 43, 186, 40, 86, 168, 180, 155, 16, 93, 26, 166, 119, 159, 56, 12, 44, 46, 143, 49, 25, 176, 158, 92, 147, 54, 172, 182, 64, 157, 112, 38, 39, 11, 6, 127, 48, 151, 82, 4, 36, 183, 88, 126, 117, 111, 188, 138, 65, 70, 170, 133, 137, 146, 128, 114, 148, 141, 125, 10, 41, 116, 33, 99, 81, 187, 130, 131, 107, 60, 90, 173, 13, 71, 15, 106, 3, 149, 154, 181, 174, 190, 27, 177, 18, 21, 22, 83, 91, 150, 14, 96, 53, 0, 145, 67, 68, 144, 184, 59, 23, 118, 115, 135, 55, 134, 102, 8, 169, 85, 156, 97, 63, 104, 95, 52, 98, 139, 24, 78, 179, 19, 28, 69, 58, 109, 57, 164, 31, 84, 140, 103, 77, 123, 171, 72, 79, 152, 35, 80, 7, 185, 167, 9, 100, 142, 89, 30, 120, 178, 101,

the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is

152 1634 7484 23081 24142 26799 33620 40989 41902 44319 44378 45067 140 701 5137 7313 12672 16929 20359 27052 30236 33846 36254 46973 748 769 2891 7812 9964 15629 19104 20551 25796 28144 31518 34124 542 976 2279 18904 20877 24190 25903 28129 36804 41152 41957 46888 173 960 2926 11682 12304 13284 18037 22702 30255 33718 34073 37152 78 1487 4898 7472 8033 10631 11732 19334 24577 34586 38651 43639 594 1095 1857 2368 8909 17295 17546 21865 23257 31273 37013 41454 72 419 1596 7849 16093 23167 26923 31883 36092 40348 44500 866 1120 1568 1986 3532 20094 21663 26664 26970 33542 42578 868 917 1216 12018 15402 20691 24736 33133 36692 40276 46616 955 1070 1749 7988 10235 19174 22733 24283 27985 38200 44029 613 1729 1787 19542 21227 21376 31057 36104 36874 38078 42445 86 1555 1644 4633 14402 14997 25724 31382 31911 32224 43900 353 1132 1246 5544 7248 17887 25769 27008 28773 33188 44663 600 958 1376 6417 6814 17587 20680 25376 29522 31396 40526 179 528 1472 2481 5589 15696 20148 28040 29690 32370 42163 122 144 681 6613 11230 20862 26396 27737 35928 39396 42713 934 1256 1420 3881 4487 5830 7897 9587 17940 40333 41925 622 1458 1490 16541 18443 19401 24860 26981 28157 32875 38755 1017 1143 1511 2169 17322 24662 25971 29149 31450 31670 34779 935 1084 1534 2918 10596 11534 17476 27269 30344 31104 37975 173 532 1766 8001 10483 17002 19002 26759 31006 43466 47443 221 610 1795 9197 11770 12793 14875 30177 30610 42274 43888 188 439 1332 7030 9246 15150 26060 26541 27190 28259 36763 812 1643 1750 7446 7888 7995 18804 21646 28995 30727 39065 44 481 555 5618 9621 9873 19182 22059 42510 45343 46058 156 532 1799 6258 18733 19988 23237 27657 30835 34738 39503 1128 1553 1790 8372 11543 13764 17062 28627 38502 40796 42461 564 777 1286 3446 5566 12105 16038 18918 21802 25954 28137 1167 1178 1770 4151 11422 11833 16823 17799 19188 22517 29979 576 638 1364 12257 22028 24243 24297 31788 36398 38409 47211 334 592 940 2865 12075 12708 21452 31961 32150 35723 46278 1205 1267 1721 9293 18685 18917 23490 27678 37645 40114 45733 189 628 821 17066 19218 21462 25452 26858 38408 38941 42354 190 951 1019 5572 7135 15647 32613 33863 33981 35670 43727 84 1003 1597 12597 15567 21221 21891 23151 23964 24816 46178 756 1262 1345 6694 6893 9300 9497 17950 19082 35668 38447 848 948 1560 6591 12529 12535 20567 23882 34481 46531 46541 504 631 777 10585 12330 13822 15388 23332 27688 35955 38051 676 1484 1575 2215 5830 6049 13558 25034 33602 35663 41025 1298 1427 1732 13930 15611 19462 20975 23200 30460 30682 34883 1491 1593 1615 4289 7010 10264 21047 26704 27024 29658 46766 969 1730 1748 2217 7181 7623 15860 21332 28133 28998 36077 302 1216 1374 5177 6849 7239 10255 34952 37908 39911 41738 220 362 1491 5235 5439 22708 29228 29481 33272 36831 46487 4 728 1279 4579 8325 8505 27604 31437 33574 41716 45082 472 735 1558 4454 6957 14867 18307 22437 38304 42054 45307 85 466 851 3669 7119 32748 32845 41914 42595 42600 45101 52 553 824 2994 4569 12505 24738 33258 37121 43381 44753 37 495 1553 7684 8908 12412 15563 16461 17872 29292 30619 254 1057 1481 9971 18408 19815 28569 29164 39281 42723 45604 16 1213 1614 4352 8091 8847 10022 24394 35661 43800 44362 395 750 888 2582 3772 4151 26025 36367 42326 42673 47393 862 1379 1441 6413 25621 28378 34869 35491 41774 44165 45411 46 213 1597 2771 4694 4923 17101 17212 19347 22002 43226 1339 1544 1610 13522 14840 15355 29399 30125 33685 36350 37672 251 1162 1260 9766 13137 34769 36646 43313 43736 43828 45151 214 1002 1688 5357 19091 19213 24460 28843 32869 35013 39791 646 733 1735 11175 11336 12043 22962 33892 35646 37116 38655 293 927 1064 4818 5842 10983 12871 17804 33127 41604 46588 10927 15514 22748 34850 37645 40669 41583 44090 3329 7548 8092 11659 16832 35304 46738 46888 3510 5915 9603 30333 37198 42866 44361 46416 2575 5311 9421 13410 15375 34017 37136 43990 12468 14492 24417 26394 38565 38936 41899 45593.

A third transmission method according to the present technology is a transmission method including: an encoding step of performing LDPC encoding on the basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 7/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in which in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

148, 189, 3, 121, 80, 135, 7, 96, 46, 109, 190, 111, 118, 23, 5, 149, 19, 140, 106, 36, 161, 71, 6, 176, 160, 76, 8, 168, 171, 173, 40, 37, 25, 50, 164, 108, 139, 31, 127, 142, 163, 177, 24, 20, 157, 83, 116, 42, 73, 69, 88, 184, 147, 136, 187, 49, 45, 35, 170, 62, 63, 181, 117, 123, 122, 72, 55, 53, 133, 159, 94, 175, 179, 158, 97, 93, 13, 130, 144, 81, 68, 2, 64, 155, 119, 43, 143, 1, 112, 18, 146, 172, 132, 191, 134, 61, 138, 9, 178, 103, 15, 47, 154, 17, 152, 153, 107, 115, 39, 166, 33, 104, 56, 52, 60, 131, 141, 78, 186, 162, 54, 0, 85, 12, 86, 77, 126, 34, 180, 10, 87, 38, 4, 26, 79, 27, 98, 66, 75, 67, 110, 101, 128, 16, 22, 28, 151, 21, 99, 74, 11, 100, 65, 58, 150, 145, 14, 59, 102, 51, 48, 113, 92, 167, 188, 174, 156, 114, 82, 125, 124, 70, 137, 90, 30, 44, 57, 105, 95, 165, 29, 89, 41, 169, 120, 91, 32, 183, 129, 182, 185, 84,

the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 4680, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is

1012 3997 5398 5796 21940 23609 25002 28007 32214 33822 38194 1110 4016 5752 10837 15440 15952 17802 27468 32933 33191 35420 95 1953 6554 11381 12839 12880 22901 26742 26910 27621 37825 1146 2232 5658 13131 13785 16771 17466 20561 29400 32962 36879 2023 3420 5107 10789 12303 13316 14428 24912 35363 36348 38787 3283 3637 12474 14376 20459 22584 23093 28876 31485 31742 34849 1807 3890 4865 7562 9091 13778 18361 21934 24548 34267 38260 1613 3620 10165 11464 14071 20675 20803 26814 27593 29483 36485 849 3946 8585 9208 9939 14676 14990 19276 23459 30577 36838 1890 2583 5951 6003 11943 13641 16319 18379 22957 24644 33430 1936 3939 5267 6314 12665 19626 20457 22010 27958 30238 32976 2153 4318 6782 13048 17730 17923 24137 24741 25594 32852 33209 1869 4262 6616 13522 19266 19384 22769 28883 30389 35102 36019 3037 3116 7478 7841 10627 10908 14060 14163 23772 27946 37835 1668 3125 7485 8525 14659 22834 24080 24838 30890 33391 36788 1623 2836 6776 8549 11448 23281 32033 32729 33650 34069 34607 101 1420 5172 7475 11673 18807 21367 23095 26368 30888 37882 3874 3940 4823 16485 21601 21655 21885 25541 30177 31656 35067 592 643 4847 6870 7671 10412 25081 33412 33478 33495 35976 2578 2677 12592 17140 17185 21962 23206 23838 27624 32594 34828 3058 3443 4959 21179 22411 24033 26004 26489 26775 33816 36694 91 2998 10137 11957 12444 22330 24300 26008 26441 26521 38191 889 1840 8881 10228 12495 18162 22259 23385 25687 35853 38848 1332 3031 13482 14262 15897 23112 25954 28035 34898 36286 36991 2505 2599 10980 15245 20084 20114 24496 26309 31139 34090 37258 599 1778 8935 16154 19546 23537 24938 32059 32406 35564 37175 392 1777 4793 8050 10543 10668 14823 25252 32922 36658 37832 1680 2630 7190 7880 10894 20675 27523 33460 33733 34000 35829 532 3750 5075 10603 12466 19838 24231 24998 27647 35111 38617 1786 3066 11367 12452 13896 15346 24646 25509 26109 30358 37392 1027 1659 6483 16919 17636 18905 19741 30579 35934 36515 37617 2064 2354 14085 16460 21378 21719 22981 23329 31701 32057 32640 2009 4421 7595 8790 12803 17649 18527 24246 27584 28757 31794 364 646 9398 13898 17486 17709 20911 31493 31810 32019 33341 2246 3760 4911 19338 25792 27511 28689 30634 31928 34984 36605 3178 3544 8858 9336 9602 12290 16521 27872 28391 28422 36105 1981 2209 12718 20656 21253 22574 28653 29967 33692 36759 37871 787 1545 7652 8376 9628 9995 10289 16260 17606 22673 34564 795 4580 12749 16670 18727 19131 19449 26152 29165 30820 31678 1577 2980 8659 12301 13813 14838 20782 23068 30185 34308 34676 84 434 13572 21777 24581 28397 28490 32547 33282 34655 37579 2927 4440 8979 14992 19009 20435 23558 26280 31320 35106 37704 1974 2712 6552 8585 10051 14848 15186 22968 24285 25878 36054 585 1990 3457 5010 8808 9 2792 4678 22666 32922 342 507 861 18844 32947 554 3395 4094 8147 34616 356 2061 2801 20330 38214 425 2432 4573 7323 28157 73 1192 2618 7812 17947 842 1053 4088 10818 24053 1234 1249 4171 6645 37350 1498 2113 4175 6432 17014 524 2135 2205 6311 7502 191 954 3166 28938 31869 548 586 4101 12129 25819 127 2352 3215 6791 13523 286 4262 4423 14087 38061 1645 3551 4209 14083 15827 719 1087 2813 32857 34499 651 2752 4548 25139 25514 1702 4186 4478 10785 33263 34 3157 4196 5811 36555 643 649 1524 6587 27246 291 836 1036 18936 19201 78 1099 4174 18305 36119 3083 3173 4667 27349 32057 3449 4090 4339 18334 24596 503 3816 4465 29204 35316 102 1693 1799 17180 35877 288 324 1237 16167 33970 224 2831 3571 17861 28530 1202 2803 2834 4943 31485 1112 2196 3027 29308 37101 4242 4291 4503 16344 28769 1020 1927 3349 9686 33845 3179 3304 3891 8448 37247 1076 2319 4512 17010 18781 987 1391 3781 12318 35710 2268 3467 3619 15764 25608 764 1135 2224 8647 17486 2091 4081 4648 8101 33818 471 3668 4069 14925 36242 932 2140 3428 12523 33270 5840 8959 12039 15972 38496 5960 7759 10493 31160 38054 10380 14835 26024 35399 36517 5260 7306 13419 28804 31112 12747 23075 32458 36239 37437 14096 16976 21598 32228 34672 5024 5769 21798 22675 25316 8617 14189 17874 22776 29780 7628 13623 16676 30019 33213 14090 14254 18987 21720 38550 17306 17709 19135 22995 28597 13137 18028 23943 27468 37156 7704 8171 10815 28138 29526.

A third reception device according to the present technology is a reception device including a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, in which the transmission device includes: an encoding unit that performs LDPC encoding on the basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 7/16; a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

148, 189, 3, 121, 80, 135, 7, 96, 46, 109, 190, 111, 118, 23, 5, 149, 19, 140, 106, 36, 161, 71, 6, 176, 160, 76, 8, 168, 171, 173, 40, 37, 25, 50, 164, 108, 139, 31, 127, 142, 163, 177, 24, 20, 157, 83, 116, 42, 73, 69, 88, 184, 147, 136, 187, 49, 45, 35, 170, 62, 63, 181, 117, 123, 122, 72, 55, 53, 133, 159, 94, 175, 179, 158, 97, 93, 13, 130, 144, 81, 68, 2, 64, 155, 119, 43, 143, 1, 112, 18, 146, 172, 132, 191, 134, 61, 138, 9, 178, 103, 15, 47, 154, 17, 152, 153, 107, 115, 39, 166, 33, 104, 56, 52, 60, 131, 141, 78, 186, 162, 54, 0, 85, 12, 86, 77, 126, 34, 180, 10, 87, 38, 4, 26, 79, 27, 98, 66, 75, 67, 110, 101, 128, 16, 22, 28, 151, 21, 99, 74, 11, 100, 65, 58, 150, 145, 14, 59, 102, 51, 48, 113, 92, 167, 188, 174, 156, 114, 82, 125, 124, 70, 137, 90, 30, 44, 57, 105, 95, 165, 29, 89, 41, 169, 120, 91, 32, 183, 129, 182, 185, 84,

the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 4680, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is

1012 3997 5398 5796 21940 23609 25002 28007 32214 33822 38194 1110 4016 5752 10837 15440 15952 17802 27468 32933 33191 35420 95 1953 6554 11381 12839 12880 22901 26742 26910 27621 37825 1146 2232 5658 13131 13785 16771 17466 20561 29400 32962 36879 2023 3420 5107 10789 12303 13316 14428 24912 35363 36348 38787 3283 3637 12474 14376 20459 22584 23093 28876 31485 31742 34849 1807 3890 4865 7562 9091 13778 18361 21934 24548 34267 38260 1613 3620 10165 11464 14071 20675 20803 26814 27593 29483 36485 849 3946 8585 9208 9939 14676 14990 19276 23459 30577 36838 1890 2583 5951 6003 11943 13641 16319 18379 22957 24644 33430 1936 3939 5267 6314 12665 19626 20457 22010 27958 30238 32976 2153 4318 6782 13048 17730 17923 24137 24741 25594 32852 33209 1869 4262 6616 13522 19266 19384 22769 28883 30389 35102 36019 3037 3116 7478 7841 10627 10908 14060 14163 23772 27946 37835 1668 3125 7485 8525 14659 22834 24080 24838 30890 33391 36788 1623 2836 6776 8549 11448 23281 32033 32729 33650 34069 34607 101 1420 5172 7475 11673 18807 21367 23095 26368 30888 37882 3874 3940 4823 16485 21601 21655 21885 25541 30177 31656 35067 592 643 4847 6870 7671 10412 25081 33412 33478 33495 35976 2578 2677 12592 17140 17185 21962 23206 23838 27624 32594 34828 3058 3443 4959 21179 22411 24033 26004 26489 26775 33816 36694 91 2998 10137 11957 12444 22330 24300 26008 26441 26521 38191 889 1840 8881 10228 12495 18162 22259 23385 25687 35853 38848 1332 3031 13482 14262 15897 23112 25954 28035 34898 36286 36991 2505 2599 10980 15245 20084 20114 24496 26309 31139 34090 37258 599 1778 8935 16154 19546 23537 24938 32059 32406 35564 37175 392 1777 4793 8050 10543 10668 14823 25252 32922 36658 37832 1680 2630 7190 7880 10894 20675 27523 33460 33733 34000 35829 532 3750 5075 10603 12466 19838 24231 24998 27647 35111 38617 1786 3066 11367 12452 13896 15346 24646 25509 26109 30358 37392 1027 1659 6483 16919 17636 18905 19741 30579 35934 36515 37617 2064 2354 14085 16460 21378 21719 22981 23329 31701 32057 32640 2009 4421 7595 8790 12803 17649 18527 24246 27584 28757 31794 364 646 9398 13898 17486 17709 20911 31493 31810 32019 33341 2246 3760 4911 19338 25792 27511 28689 30634 31928 34984 36605 3178 3544 8858 9336 9602 12290 16521 27872 28391 28422 36105 1981 2209 12718 20656 21253 22574 28653 29967 33692 36759 37871 787 1545 7652 8376 9628 9995 10289 16260 17606 22673 34564 795 4580 12749 16670 18727 19131 19449 26152 29165 30820 31678 1577 2980 8659 12301 13813 14838 20782 23068 30185 34308 34676 84 434 13572 21777 24581 28397 28490 32547 33282 34655 37579 2927 4440 8979 14992 19009 20435 23558 26280 31320 35106 37704 1974 2712 6552 8585 10051 14848 15186 22968 24285 25878 36054 585 1990 3457 5010 8808 9 2792 4678 22666 32922 342 507 861 18844 32947 554 3395 4094 8147 34616 356 2061 2801 20330 38214 425 2432 4573 7323 28157 73 1192 2618 7812 17947 842 1053 4088 10818 24053 1234 1249 4171 6645 37350 1498 2113 4175 6432 17014 524 2135 2205 6311 7502 191 954 3166 28938 31869 548 586 4101 12129 25819 127 2352 3215 6791 13523 286 4262 4423 14087 38061 1645 3551 4209 14083 15827 719 1087 2813 32857 34499 651 2752 4548 25139 25514 1702 4186 4478 10785 33263 34 3157 4196 5811 36555 643 649 1524 6587 27246 291 836 1036 18936 19201 78 1099 4174 18305 36119 3083 3173 4667 27349 32057 3449 4090 4339 18334 24596 503 3816 4465 29204 35316 102 1693 1799 17180 35877 288 324 1237 16167 33970 224 2831 3571 17861 28530 1202 2803 2834 4943 31485 1112 2196 3027 29308 37101 4242 4291 4503 16344 28769 1020 1927 3349 9686 33845 3179 3304 3891 8448 37247 1076 2319 4512 17010 18781 987 1391 3781 12318 35710 2268 3467 3619 15764 25608 764 1135 2224 8647 17486 2091 4081 4648 8101 33818 471 3668 4069 14925 36242 932 2140 3428 12523 33270 5840 8959 12039 15972 38496 5960 7759 10493 31160 38054 10380 14835 26024 35399 36517 5260 7306 13419 28804 31112 12747 23075 32458 36239 37437 14096 16976 21598 32228 34672 5024 5769 21798 22675 25316 8617 14189 17874 22776 29780 7628 13623 16676 30019 33213 14090 14254 18987 21720 38550 17306 17709 19135 22995 28597 13137 18028 23943 27468 37156 7704 8171 10815 28138 29526.

A fourth transmission method according to the present technology is a transmission method including: an encoding step of performing LDPC encoding on the basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 9/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in which in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

67, 20, 9, 75, 143, 94, 144, 122, 56, 88, 180, 72, 102, 100, 113, 157, 170, 59, 128, 162, 26, 38, 61, 156, 115, 117, 190, 77, 22, 74, 119, 12, 8, 179, 182, 85, 188, 191, 154, 41, 58, 142, 186, 107, 73, 189, 15, 130, 127, 160, 55, 19, 45, 137, 124, 133, 146, 43, 60, 183, 153, 177, 123, 181, 95, 49, 140, 4, 51, 3, 21, 164, 83, 187, 148, 11, 168, 149, 92, 65, 30, 90, 23, 116, 57, 161, 125, 175, 129, 126, 97, 14, 96, 66, 37, 178, 64, 173, 184, 80, 101, 34, 81, 131, 76, 147, 47, 135, 111, 121, 44, 68, 98, 48, 120, 40, 87, 176, 104, 106, 28, 163, 52, 1, 152, 79, 42, 139, 16, 2, 71, 7, 109, 114, 112, 54, 62, 169, 35, 150, 171, 110, 50, 108, 105, 69, 118, 84, 39, 132, 63, 31, 18, 134, 103, 185, 6, 145, 24, 70, 36, 29, 5, 93, 99, 33, 82, 89, 167, 174, 27, 165, 91, 138, 155, 32, 159, 141, 136, 151, 25, 158, 86, 17, 13, 172, 53, 10, 46, 166, 0, 78,

the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is

110 3064 6740 7801 10228 13445 17599 17891 17979 18044 19923 21848 23262 25585 25968 30124

1578 8914 9141 9731 10605 11690 12824 18127 18458 24648 24950 25150 26323 26514 27385 27460

3054 3640 3923 7332 10770 12215 14455 14849 15619 20870 22033 26427 28067 28560 29777 29780

1348 4248 5479 8902 9101 9356 10581 11614 12813 21554 22985 23701 24099 24575 24786 27370

3266 8358 16544 16689 16693 16823 17565 18543 19229 21121 23799 24981 25423 28997 29808 30202

320 1198 1549 5407 6080 8542 9352 12418 13391 14736 15012 18328 19398 23391 28117 28793

2114 3294 3770 5225 5556 5991 7075 7889 11145 11386 16561 18956 19034 23605 26085 27132

3623 4011 4225 5249 5489 5711 7240 9831 10458 14697 15420 16015 17782 23244 24215 24386

2624 2750 3871 8247 11135 13702 19290 22209 22975 23811 23931 24872 25154 25165 28375 30200

1060 1240 2040 2382 7723 9165 9656 10398 14517 16653 21241 22348 23476 27203 28443 28445

1070 1233 3416 6633 11736 12808 15454 16505 18720 20162 21425 21874 26069 26855 27292 27978

420 5524 10279 11218 12500 12913 15389 15824 19414 19588 21138 23846 26621 27907 28594 28781

151 1356 2323 3289 4501 10573 13667 14642 16127 17040 17475 18055 24061 26204 26567 29277

1410 3656 4080 6963 8834 10527 17490 17584 18065 19234 22211 22338 23746 24662 29863 30227

1924 2694 3285 8761 9693 11005 17592 21259 21322 21546 21555 24044 24173 26988 27640 28506

1069 6483 6554 9027 11655 12453 16595 17877 18350 18995 21304 21442 23836 25468 28820 29453

149 1621 2199 3141 8403 11974 14969 16197 18844 21027 21921 22266 22399 22691 25727 27721

3689 4839 7971 8419 10500 12308 13435 14487 16502 16622 17229 17468 22710 23904 25074 28508

1270 7007 9830 12698 14204 16075 17613 19391 21362 21726 21816 23014 23651 26419 26748 27195

96 1953 2456 2712 2809 3196 5939 10634 21828 24606 26169 26801 27391 28578 29725 30142

832 3394 4145 5375 6199 7122 7405 7706 10136 10792 15058 15860 21881 23908 25174 25837

730 1735 2917 4106 5004 5849 8194 8943 9136 17599 18456 20191 22798 27935 29559

6238 6776 6799 9142 11199 11867 15979 16830 18110 18396 21897 22590 24020 29578 29644

407 2138 4493 7979 8225 9467 11956 12940 15566 15809 16058 18211 22073 28314 28713

957 1552 1869 4388 7642 7904 13408 13453 16431 19327 21444 22188 25719 28511 29192

3617 8663 22378 28704

8598 12647 19278 22416

15176 16377 16644 22732

12463 12711 18341

11079 13446 29071

2446 4068 8542

10838 11660 27428

16403 21750 23199

9181 16572 18381

7227 18770 21858

7379 9316 16247

8923 14861 29618

6531 24652 26817

5564 8875 18025

8019 14642 21169

16683 17257 29298

4078 6023 8853

13942 15217 15501

7484 8302 27199

671 14966 20886

1240 11897 14925

12800 25474 28603

3576 5308 11168

13430 15265 18232

3439 5544 21849

3257 16996 23750

1865 14153 22669

7640 15098 17364

6137 19401 24836

5986 9035 11444

4799 20865 29150

8360 23554 29246

2002 18215 22258

9679 11951 26583

2844 12330 18156

3744 6949 14754

8262 10288 27142

1087 16563 22815

1328 13273 21749

2092 9191 28045

3250 10549 18252

13975 15172 17135

2520 26310 28787

4395 8961 26753

6413 15437 19520

5809 10936 17089

1670 13574 25125

5865 6175 21175

8391 11680 22660

5485 11743 15165

21021 21798 30209

12519 13402 26300

3472 25935 26412

3377 7398 28867

2430 24650 29426

3364 13409 22914

6838 13491 16229

18393 20764 28078

289 20279 24906

4732 6162 13569

8993 17053 29387

2210 5024 24030

21 22976 24053

12359 15499 28251

4640 11480 24391

1083 7965 16573

13116 23916 24421

10129 16284 23855

1758 3843 21163

5626 13543 26708

14918 17713 21718

13556 20450 24679

3911 16778 29952

11735 13710 22611

5347 21681 22906

6912 12045 15866

713 15429 23281

7133 17440 28982

12355 17564 28059

7658 11158 29885

17610 18755 28852

7680 16212 30111

8812 10144 15718.

A fourth reception device according to the present technology is a reception device including a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, in which the transmission device includes: an encoding unit that performs LDPC encoding on the basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 9/16, a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

67, 20, 9, 75, 143, 94, 144, 122, 56, 88, 180, 72, 102, 100, 113, 157, 170, 59, 128, 162, 26, 38, 61, 156, 115, 117, 190, 77, 22, 74, 119, 12, 8, 179, 182, 85, 188, 191, 154, 41, 58, 142, 186, 107, 73, 189, 15, 130, 127, 160, 55, 19, 45, 137, 124, 133, 146, 43, 60, 183, 153, 177, 123, 181, 95, 49, 140, 4, 51, 3, 21, 164, 83, 187, 148, 11, 168, 149, 92, 65, 30, 90, 23, 116, 57, 161, 125, 175, 129, 126, 97, 14, 96, 66, 37, 178, 64, 173, 184, 80, 101, 34, 81, 131, 76, 147, 47, 135, 111, 121, 44, 68, 98, 48, 120, 40, 87, 176, 104, 106, 28, 163, 52, 1, 152, 79, 42, 139, 16, 2, 71, 7, 109, 114, 112, 54, 62, 169, 35, 150, 171, 110, 50, 108, 105, 69, 118, 84, 39, 132, 63, 31, 18, 134, 103, 185, 6, 145, 24, 70, 36, 29, 5, 93, 99, 33, 82, 89, 167, 174, 27, 165, 91, 138, 155, 32, 159, 141, 136, 151, 25, 158, 86, 17, 13, 172, 53, 10, 46, 166, 0, 78,

the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is

110 3064 6740 7801 10228 13445 17599 17891 17979 18044 19923 21848 23262 25585 25968 30124

1578 8914 9141 9731 10605 11690 12824 18127 18458 24648 24950 25150 26323 26514 27385 27460

3054 3640 3923 7332 10770 12215 14455 14849 15619 20870 22033 26427 28067 28560 29777 29780

1348 4248 5479 8902 9101 9356 10581 11614 12813 21554 22985 23701 24099 24575 24786 27370

3266 8358 16544 16689 16693 16823 17565 18543 19229 21121 23799 24981 25423 28997 29808 30202

320 1198 1549 5407 6080 8542 9352 12418 13391 14736 15012 18328 19398 23391 28117 28793

2114 3294 3770 5225 5556 5991 7075 7889 11145 11386 16561 18956 19034 23605 26085 27132

3623 4011 4225 5249 5489 5711 7240 9831 10458 14697 15420 16015 17782 23244 24215 24386

2624 2750 3871 8247 11135 13702 19290 22209 22975 23811 23931 24872 25154 25165 28375 30200

1060 1240 2040 2382 7723 9165 9656 10398 14517 16653 21241 22348 23476 27203 28443 28445

1070 1233 3416 6633 11736 12808 15454 16505 18720 20162 21425 21874 26069 26855 27292 27978

420 5524 10279 11218 12500 12913 15389 15824 19414 19588 21138 23846 26621 27907 28594 28781

151 1356 2323 3289 4501 10573 13667 14642 16127 17040 17475 18055 24061 26204 26567 29277

1410 3656 4080 6963 8834 10527 17490 17584 18065 19234 22211 22338 23746 24662 29863 30227

1924 2694 3285 8761 9693 11005 17592 21259 21322 21546 21555 24044 24173 26988 27640 28506

1069 6483 6554 9027 11655 12453 16595 17877 18350 18995 21304 21442 23836 25468 28820 29453

149 1621 2199 3141 8403 11974 14969 16197 18844 21027 21921 22266 22399 22691 25727 27721

3689 4839 7971 8419 10500 12308 13435 14487 16502 16622 17229 17468 22710 23904 25074 28508

1270 7007 9830 12698 14204 16075 17613 19391 21362 21726 21816 23014 23651 26419 26748 27195

96 1953 2456 2712 2809 3196 5939 10634 21828 24606 26169 26801 27391 28578 29725 30142

832 3394 4145 5375 6199 7122 7405 7706 10136 10792 15058 15860 21881 23908 25174 25837

730 1735 2917 4106 5004 5849 8194 8943 9136 17599 18456 20191 22798 27935 29559

6238 6776 6799 9142 11199 11867 15979 16830 18110 18396 21897 22590 24020 29578 29644

407 2138 4493 7979 8225 9467 11956 12940 15566 15809 16058 18211 22073 28314 28713

957 1552 1869 4388 7642 7904 13408 13453 16431 19327 21444 22188 25719 28511 29192

3617 8663 22378 28704

8598 12647 19278 22416

15176 16377 16644 22732

12463 12711 18341

11079 13446 29071

2446 4068 8542

10838 11660 27428

16403 21750 23199

9181 16572 18381

7227 18770 21858

7379 9316 16247

8923 14861 29618

6531 24652 26817

5564 8875 18025

8019 14642 21169

16683 17257 29298

4078 6023 8853

13942 15217 15501

7484 8302 27199

671 14966 20886

1240 11897 14925

12800 25474 28603

3576 5308 11168

13430 15265 18232

3439 5544 21849

3257 16996 23750

1865 14153 22669

7640 15098 17364

6137 19401 24836

5986 9035 11444

4799 20865 29150

8360 23554 29246

2002 18215 22258

9679 11951 26583

2844 12330 18156

3744 6949 14754

8262 10288 27142

1087 16563 22815

1328 13273 21749

2092 9191 28045

3250 10549 18252

13975 15172 17135

2520 26310 28787

4395 8961 26753

6413 15437 19520

5809 10936 17089

1670 13574 25125

5865 6175 21175

8391 11680 22660

5485 11743 15165

21021 21798 30209

12519 13402 26300

3472 25935 26412

3377 7398 28867

2430 24650 29426

3364 13409 22914

6838 13491 16229

18393 20764 28078

289 20279 24906

4732 6162 13569

8993 17053 29387

2210 5024 24030

21 22976 24053

12359 15499 28251

4640 11480 24391

1083 7965 16573

13116 23916 24421

10129 16284 23855

1758 3843 21163

5626 13543 26708

14918 17713 21718

13556 20450 24679

3911 16778 29952

11735 13710 22611

5347 21681 22906

6912 12045 15866

713 15429 23281

7133 17440 28982

12355 17564 28059

7658 11158 29885

17610 18755 28852

7680 16212 30111

8812 10144 15718.

A fifth transmission method according to the present technology is a transmission method including: an encoding step of performing LDPC encoding on the basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 11/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in which in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

84, 126, 45, 76, 121, 91, 52, 162, 79, 187, 134, 108, 47, 16, 72, 119, 43, 107, 98, 135, 147, 110, 0, 60, 4, 61, 117, 24, 167, 65, 40, 55, 73, 112, 85, 35, 156, 95, 137, 171, 9, 11, 54, 131, 138, 157, 152, 111, 183, 161, 41, 69, 21, 94, 113, 8, 153, 39, 57, 143, 86, 12, 188, 184, 15, 30, 118, 136, 64, 169, 148, 22, 6, 68, 168, 78, 105, 101, 190, 3, 59, 124, 170, 62, 87, 46, 28, 29, 186, 2, 25, 177, 140, 53, 154, 37, 18, 189, 93, 114, 33, 1, 158, 122, 103, 5, 104, 80, 166, 34, 106, 51, 10, 180, 139, 125, 178, 100, 13, 70, 142, 185, 159, 50, 66, 102, 150, 127, 160, 92, 81, 173, 115, 144, 145, 128, 74, 88, 20, 116, 179, 96, 17, 155, 175, 75, 165, 7, 191, 149, 44, 23, 99, 48, 163, 42, 63, 164, 90, 120, 27, 31, 14, 19, 32, 174, 26, 67, 89, 97, 56, 146, 82, 133, 129, 109, 71, 58, 130, 182, 123, 176, 49, 36, 181, 38, 141, 151, 83, 77, 172, 132,

the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is

983 2226 4091 5418 5824 6483 6914 8239 8364 10220 10322 15658 16928 17307 18061

1584 5655 6787 7213 7270 8585 8995 9294 9832 9982 11185 12221 12889 17573 19096

319 1077 1796 2421 6574 11763 13465 14527 15147 15218 16000 18284 20199 21095 21194

767 1018 3780 3826 4288 4855 7169 7431 9151 10097 10919 12050 13261 19816 20932

173 692 3552 5046 6523 6784 9542 10482 14658 14663 15168 16153 16410 17546 20989

2214 2286 2445 2856 3562 3615 3970 6065 7117 7989 8180 15971 20253 21312 21428 532 1361 1905 3577 5147 10409 11348 11660 15230 17283 18724 20190 20542 21159 21282

3242 5061 7587 7677 8614 8834 9130 9135 9331 13480 13544 14263 15438 20548 21174

1507 4159 4946 5215 5653 6385 7131 8049 10198 10499 12215 14105 16118 17016 21371

212 1856 1981 2056 6766 8123 10128 10957 11159 11237 12893 14064 17760 18933 19009

329 5552 5948 6484 10108 10127 10816 13210 14985 15110 15565 15969 17136 18504 20818

4753 5744 6511 7062 7355 8379 8817 13503 13650 14014 15393 15640 18127 18595 20426

1152 1707 4013 5932 8540 9077 11521 11923 11954 12529 13519 15641 16262 17874 19386

858 2355 2511 3125 5531 6472 8146 11423 11558 11760 13556 15194 20782 20988 21261

216 1722 2750 3809 6210 8233 9183 10734 11339 12321 12898 15902 17437 19085 21588

1560 1718 1757 2292 2349 3992 6943 7369 7806 10282 11373 13624 14608 17087 18011

1375 1640 2015 2539 2691 2967 4344 7125 9176 9435 12378 12520 12901 15704 18897

1703 2861 2986 3574 7208 8486 9412 9879 13027 13945 14873 15546 16516 18931 21070

309 1587 3118 5472 10035 13988 15019 15322 16373 17580 17728 18125 18872 19876 20457

984 991 1203 3159 4303 5734 8850 9626 12217 17227 17269 18695 18854 19580 19684

2429 6165 6828 7761 9761 9899 9942 10151 11198 11271 13184 14026 14560 18962 20570

876 1074 5177 5185 6415 6451 10856 11603 14590 14658 16293 17221 19273 19319 20447

557 607 2473 5002 6601 9876 10284 10809 13563 14849 15710 16798 17509 18927 21306

939 1271 3085 5054 5723 5959 7530 10912 13375 16696 18753 19673 20328 21068 21258

2802 3312 5015 6041 6943 7606 9375 12116 12868 12964 13374 13594 14978 16125 18621

3002 6512 6965 6967 8504 10777 11217 11931 12647 12686 12740 12900 12958 13870 17860

151 3874 4228 7837 10244 10589 14530 15323 16462 17711 18995 19363 19376 19540 20641

1249 2946 2959 3330 4264 7797 10652 11845 12987 15974 16536 17520 19851 20150 20172

4769 11033 14937

1431 2870 15158

9416 14905 20800

1708 9944 16952

1116 1179 20743

3665 8987 16223

655 11424 17411

42 2717 11613

2787 9015 15081

3718 7305 11822

18306 18499 18843

1208 4586 10578

9494 12676 13710

10580 15127 20614

4439 15646 19861

5255 12337 14649

2532 7552 10813

1591 7781 13020

7264 8634 17208

7462 10069 17710

1320 3382 6439

4057 9762 11401

1618 7604 19881

3858 16826 17768

6158 11759 19274

3767 11872 15137

2111 5563 16776

1888 15452 17925

2840 15375 16376

3695 11232 16970

10181 16329 17920

9743 13974 17724

29 16450 20509

2393 17877 19591

1827 15175 15366

3771 14716 18363

5585 14762 19813

7186 8104 12067

2554 12025 15873

2208 5739 6150

2816 12745 17143

9363 11582 17976

5834 8178 12517

3546 15667 19511

5211 10685 20833

3399 7774 16435

3767 4542 8775

4404 6349 19426

4812 11088 16761

5761 11289 17985

9989 11488 15986

10200 16710 20899

6970 12774 20558

1304 2495 3507

5236 7678 10437

4493 10472 19880

1883 14768 21100

352 18797 20570

1411 3221 4379

3304 11013 18382

14864 16951 18782

2887 15658 17633

7109 7383 19956

4293 12990 13934

9890 15206 15786

2987 5455 8787

5782 7137 15981

736 1961 10441

2728 11808 21305

4663 4693 13680

1965 3668 9025

818 10532 16332

7006 16717 21102

2955 15500 20140

8274 13451 19436

3604 13158 21154

5519 6531 9995

1629 17919 18532

15199 16690 16884

5177 5869 14843

5 5088 19940

16910 20686 21206

10662 11610 17578

3378 4579 12849

5947 19300 19762

2545 10686 12579

4568 10814 19032

677 18652 18992

190 11377 12987

4183 6801 20025

6944 8321 15868

3311 6049 14757

7155 11435 16353

4778 5674 15973

1889 3361 7563

467 5999 10103

7613 11096 19536

2244 4442 6000

9055 13516 15414

4831 6111 10744

3792 8258 15106

6990 9168 17589

7920 11548 20786

10533 14361 19577.

A fifth reception device according to the present technology is a reception device including a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, in which the transmission device includes: an encoding unit that performs LDPC encoding on the basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 11/16; a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

84, 126, 45, 76, 121, 91, 52, 162, 79, 187, 134, 108, 47, 16, 72, 119, 43, 107, 98, 135, 147, 110, 0, 60, 4, 61, 117, 24, 167, 65, 40, 55, 73, 112, 85, 35, 156, 95, 137, 171, 9, 11, 54, 131, 138, 157, 152, 111, 183, 161, 41, 69, 21, 94, 113, 8, 153, 39, 57, 143, 86, 12, 188, 184, 15, 30, 118, 136, 64, 169, 148, 22, 6, 68, 168, 78, 105, 101, 190, 3, 59, 124, 170, 62, 87, 46, 28, 29, 186, 2, 25, 177, 140, 53, 154, 37, 18, 189, 93, 114, 33, 1, 158, 122, 103, 5, 104, 80, 166, 34, 106, 51, 10, 180, 139, 125, 178, 100, 13, 70, 142, 185, 159, 50, 66, 102, 150, 127, 160, 92, 81, 173, 115, 144, 145, 128, 74, 88, 20, 116, 179, 96, 17, 155, 175, 75, 165, 7, 191, 149, 44, 23, 99, 48, 163, 42, 63, 164, 90, 120, 27, 31, 14, 19, 32, 174, 26, 67, 89, 97, 56, 146, 82, 133, 129, 109, 71, 58, 130, 182, 123, 176, 49, 36, 181, 38, 141, 151, 83, 77, 172, 132,

the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is

983 2226 4091 5418 5824 6483 6914 8239 8364 10220 10322 15658 16928 17307 18061

1584 5655 6787 7213 7270 8585 8995 9294 9832 9982 11185 12221 12889 17573 19096

319 1077 1796 2421 6574 11763 13465 14527 15147 15218 16000 18284 20199 21095 21194

767 1018 3780 3826 4288 4855 7169 7431 9151 10097 10919 12050 13261 19816 20932

173 692 3552 5046 6523 6784 9542 10482 14658 14663 15168 16153 16410 17546 20989

2214 2286 2445 2856 3562 3615 3970 6065 7117 7989 8180 15971 20253 21312 21428 532 1361 1905 3577 5147 10409 11348 11660 15230 17283 18724 20190 20542 21159 21282

3242 5061 7587 7677 8614 8834 9130 9135 9331 13480 13544 14263 15438 20548 21174

1507 4159 4946 5215 5653 6385 7131 8049 10198 10499 12215 14105 16118 17016 21371

212 1856 1981 2056 6766 8123 10128 10957 11159 11237 12893 14064 17760 18933 19009

329 5552 5948 6484 10108 10127 10816 13210 14985 15110 15565 15969 17136 18504 20818

4753 5744 6511 7062 7355 8379 8817 13503 13650 14014 15393 15640 18127 18595 20426

1152 1707 4013 5932 8540 9077 11521 11923 11954 12529 13519 15641 16262 17874 19386

858 2355 2511 3125 5531 6472 8146 11423 11558 11760 13556 15194 20782 20988 21261

216 1722 2750 3809 6210 8233 9183 10734 11339 12321 12898 15902 17437 19085 21588

1560 1718 1757 2292 2349 3992 6943 7369 7806 10282 11373 13624 14608 17087 18011

1375 1640 2015 2539 2691 2967 4344 7125 9176 9435 12378 12520 12901 15704 18897

1703 2861 2986 3574 7208 8486 9412 9879 13027 13945 14873 15546 16516 18931 21070

309 1587 3118 5472 10035 13988 15019 15322 16373 17580 17728 18125 18872 19876 20457

984 991 1203 3159 4303 5734 8850 9626 12217 17227 17269 18695 18854 19580 19684

2429 6165 6828 7761 9761 9899 9942 10151 11198 11271 13184 14026 14560 18962 20570

876 1074 5177 5185 6415 6451 10856 11603 14590 14658 16293 17221 19273 19319 20447

557 607 2473 5002 6601 9876 10284 10809 13563 14849 15710 16798 17509 18927 21306

939 1271 3085 5054 5723 5959 7530 10912 13375 16696 18753 19673 20328 21068 21258

2802 3312 5015 6041 6943 7606 9375 12116 12868 12964 13374 13594 14978 16125 18621

3002 6512 6965 6967 8504 10777 11217 11931 12647 12686 12740 12900 12958 13870 17860

151 3874 4228 7837 10244 10589 14530 15323 16462 17711 18995 19363 19376 19540 20641

1249 2946 2959 3330 4264 7797 10652 11845 12987 15974 16536 17520 19851 20150 20172

4769 11033 14937

1431 2870 15158

9416 14905 20800

1708 9944 16952

1116 1179 20743

3665 8987 16223

655 11424 17411

42 2717 11613

2787 9015 15081

3718 7305 11822

18306 18499 18843

1208 4586 10578

9494 12676 13710

10580 15127 20614

4439 15646 19861

5255 12337 14649

2532 7552 10813

1591 7781 13020

7264 8634 17208

7462 10069 17710

1320 3382 6439

4057 9762 11401

1618 7604 19881

3858 16826 17768

6158 11759 19274

3767 11872 15137

2111 5563 16776

1888 15452 17925

2840 15375 16376

3695 11232 16970

10181 16329 17920

9743 13974 17724

29 16450 20509

2393 17877 19591

1827 15175 15366

3771 14716 18363

5585 14762 19813

7186 8104 12067

2554 12025 15873

2208 5739 6150

2816 12745 17143

9363 11582 17976

5834 8178 12517

3546 15667 19511

5211 10685 20833

3399 7774 16435

3767 4542 8775

4404 6349 19426

4812 11088 16761

5761 11289 17985

9989 11488 15986

10200 16710 20899

6970 12774 20558

1304 2495 3507

5236 7678 10437

4493 10472 19880

1883 14768 21100

352 18797 20570

1411 3221 4379

3304 11013 18382

14864 16951 18782

2887 15658 17633

7109 7383 19956

4293 12990 13934

9890 15206 15786

2987 5455 8787

5782 7137 15981

736 1961 10441

2728 11808 21305

4663 4693 13680

1965 3668 9025

818 10532 16332

7006 16717 21102

2955 15500 20140

8274 13451 19436

3604 13158 21154

5519 6531 9995

1629 17919 18532

15199 16690 16884

5177 5869 14843

5 5088 19940

16910 20686 21206

10662 11610 17578

3378 4579 12849

5947 19300 19762

2545 10686 12579

4568 10814 19032

677 18652 18992

190 11377 12987

4183 6801 20025

6944 8321 15868

3311 6049 14757

7155 11435 16353

4778 5674 15973

1889 3361 7563

467 5999 10103

7613 11096 19536

2244 4442 6000

9055 13516 15414

4831 6111 10744

3792 8258 15106

6990 9168 17589

7920 11548 20786

10533 14361 19577.

A sixth transmission method according to the present technology is a transmission method including: an encoding step of performing LDPC encoding on the basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 13/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in which in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

30, 127, 60, 115, 80, 50, 150, 39, 176, 171, 47, 104, 70, 33, 56, 3, 10, 26, 19, 149, 153, 141, 98, 46, 64, 71, 130, 107, 94, 16, 164, 169, 57, 168, 126, 157, 133, 12, 154, 135, 35, 53, 40, 183, 28, 1, 160, 67, 163, 134, 181, 59, 99, 186, 86, 36, 178, 152, 48, 117, 44, 14, 66, 172, 17, 31, 182, 166, 187, 55, 62, 143, 69, 77, 9, 113, 158, 91, 189, 84, 151, 74, 45, 97, 122, 114, 75, 41, 162, 90, 110, 106, 116, 131, 129, 188, 92, 11, 147, 108, 20, 159, 146, 51, 29, 109, 89, 6, 96, 155, 43, 111, 138, 85, 119, 5, 22, 105, 170, 4, 15, 148, 145, 63, 0, 156, 81, 68, 13, 137, 79, 103, 2, 179, 38, 180, 132, 123, 144, 167, 140, 174, 49, 37, 82, 128, 101, 21, 124, 177, 121, 8, 23, 136, 42, 27, 139, 72, 185, 18, 65, 161, 7, 125, 88, 34, 73, 184, 52, 190, 120, 102, 100, 87, 95, 118, 83, 112, 175, 78, 58, 24, 165, 54, 61, 25, 191, 76, 142, 93, 173, 32,

the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is

1031 4123 6253 6610 8007 8656 9181 9404 9596 11501 11654 11710 11994 12177

399 553 1442 2820 4402 4823 5011 5493 7070 8340 8500 9054 11201 11387 201 607 1428 2354 5358 5524 6617 6785 7708 10220 11970 12268 12339 12537

36 992 1930 4525 5837 6283 6887 7284 7489 7550 10329 11202 11399 12795 589 1564 1747 2960 3833 4502 7491 7746 8196 9567 9574 10187 10591 12947 804 1177 1414 3765 4745 7594 9126 9230 9251 10299 10336 11563 11844 12209

2774 2830 3918 4148 4963 5356 7125 7645 7868 8137 9119 9189 9206 12363 59 448 947 3622 5139 8115 9364 9548 9609 9750 10212 10937 11044 12668 715 1352 4538 5277 5729 6210 6418 6938 7090 7109 7386 9012 10737 11893 1583 2059 3398 3619 4277 6896 7484 7525 8284 9318 9817 10227 11636 12204 53 549 3010 5441 6090 9175 9336 9358 9839 10117 11307 11467 11507 12902 861 1054 1177 1201 1383 2538 4563 6451 6800 10540 11222 11757 12240 12732 330 1450 1798 2301 2652 3038 3187 3277 4324 4610 9395 10240 10796 11100 316 751 1226 1746 2124 2505 3497 3833 3891 7551 8696 9763 11978 12661 2677 2888 2904 3923 4804 5105 6855 7222 7893 7907 9674 10274 12683 12702 173 3397 3520 5131 5560 6666 6783 6893 7742 7842 9364 9442 12287 421 943 1893 1920 3273 4052 5758 5787 7043 11051 12141 12209 12500 679 792 2543 3243 3385 3576 4190 7501 8233 8302 9212 9522 12286 911 3651 4023 4462 4650 5336 5762 6506 8050 8381 9636 9724 12486 1373 1728 1911 4101 4913 5003 6859 7137 8035 9056 9378 9937 10184 515 2357 2779 2797 3163 3845 3976 6969 7704 9104 10102 11507 12700 270 1744 1804 3432 3782 4643 5946 6279 6549 7064 7393 11659 12002 261 1517 2269 3554 4762 5103 5460 6429 6464 8962 9651 10927 12268 782 1217 1395 2383 5754 6060 6540 7109 7286 7438 7846 9488 10119 2070 2247 2589 2644 3270 3875 4901 6475 8953 10090 10629 12496 12547 863 1190 1609 2971 3564 4148 5123 5262 6301 7797 7804 9517 11408 449 488 865 3549 3939 4410 4500 5700 7120 8778 9223 11660 12021 1107 1408 1883 2752 3818 4714 5979 6485 7314 7821 11290 11472 12325 713 2492 2507 2641 3576 4711 5021 5831 7334 8362 9094 9690 10778 1487 2344 5035 5336 5727 6495 9009 9345 11090 11261 11314 12383 12944 1038 1463 1472 2944 3202 5742 5793 6972 7853 8919 9808 10549 12619 134 957 2018 2140 2629 3884 5821 7319 8676 10305 10670 12031 12588 5294 9842 4396 6648 2863 5308 10467 11711 3412 6909 450 3919 5639 9801 298 4323 397 10223 4424 9051 2038 2376 5889 11321 12500 3590 4081 12684 3485 4016 9826 6 2869 8310 5983 9818 10877 2282 9346 11477 4931 6135 10473 300 2901 9937 3185 5215 7479 472 5845 5915 2476 7687 11934 3279 8782 11527 4350 7138 7144 7454 7818 8253 1391 8717 8844 1940 4736 10556 5471 7344 8089 9157 10640 11919 1343 5402 12724 2581 4118 8142 5165 9328 11386 7222 7262 12955 6711 11224 11737 401 3195 11940 6114 6969 8208 1402 7917 9738 965 7700 10139 3428 5767 12000 3501 7052 8803 1447 10504 10961 1870 1914 7762 613 2063 10520 3561 6480 10466 3389 3887 10110 995 1104 1640 1492 4122 7572 3243 9765 12415 7297 11200 11533 1959 10325 11306 1675 5313 11475 3621 4658 12790 4208 5650 8687 2467 7691 11886 3039 3190 5017 866 1375 2272 4374 6453 8228 2763 4668 4749 640 1346 6924 6588 6983 10075 3389 9260 12508 89 5799 9973 1290 2978 8038 317 742 8017 5378 5618 6586 3369 3827 4536 1000 10436 12288 3762 11384 11897 848 874 8968 1001 4751 12066 1788 6685 12397 5721 8247 9005 649 7547 9837 2263 9415 10862 3954 4111 7767 952 4393 5523 8132 8580 10906 4191 9677 12585 1071 10601 11106 3069 6943 11015 5555 8088 9537 85 2810 3100 1249 8418 8684 2743 12099 12686 2908 3691 9890 10172 10409 11615 8358 10584 12082 4902 6310 8368 4976 10047 11299 7325 8228 11092 4942 6974 8533 5782 9780 9869 15 4728 10395 369 1900 11517 3796 7434 9085 2473 9813 12636 1472 3557 6607 174 3715 4811 6263 6694 8114 4538 6635 9101 3199 8348 10057 6176 7498 7937 1837 3382 5688 8897 11342 11680 455 6465 7428 1900 3666 8968 3481 6308 10199 159 2654 12150 5602 6695 12897 3309 4899 6415 6 99 7615 1722 6386 11112 5090 8873 10718 4164 6731 12121 367 846 7678 222 6050 12711 3154 7149 7557 1556 4667 7990 2536 9712 9932 4104 7040 9983 6365 11604 12457 3393 10323 10743 724 2237 5455 108 1705 6151.

A sixth reception device according to the present technology is a reception device including a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, in which the transmission device includes: an encoding unit that performs LDPC encoding on the basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 13/16; a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

30, 127, 60, 115, 80, 50, 150, 39, 176, 171, 47, 104, 70, 33, 56, 3, 10, 26, 19, 149, 153, 141, 98, 46, 64, 71, 130, 107, 94, 16, 164, 169, 57, 168, 126, 157, 133, 12, 154, 135, 35, 53, 40, 183, 28, 1, 160, 67, 163, 134, 181, 59, 99, 186, 86, 36, 178, 152, 48, 117, 44, 14, 66, 172, 17, 31, 182, 166, 187, 55, 62, 143, 69, 77, 9, 113, 158, 91, 189, 84, 151, 74, 45, 97, 122, 114, 75, 41, 162, 90, 110, 106, 116, 131, 129, 188, 92, 11, 147, 108, 20, 159, 146, 51, 29, 109, 89, 6, 96, 155, 43, 111, 138, 85, 119, 5, 22, 105, 170, 4, 15, 148, 145, 63, 0, 156, 81, 68, 13, 137, 79, 103, 2, 179, 38, 180, 132, 123, 144, 167, 140, 174, 49, 37, 82, 128, 101, 21, 124, 177, 121, 8, 23, 136, 42, 27, 139, 72, 185, 18, 65, 161, 7, 125, 88, 34, 73, 184, 52, 190, 120, 102, 100, 87, 95, 118, 83, 112, 175, 78, 58, 24, 165, 54, 61, 25, 191, 76, 142, 93, 173, 32,

the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is

1031 4123 6253 6610 8007 8656 9181 9404 9596 11501 11654 11710 11994 12177

399 553 1442 2820 4402 4823 5011 5493 7070 8340 8500 9054 11201 11387 201 607 1428 2354 5358 5524 6617 6785 7708 10220 11970 12268 12339 12537

36 992 1930 4525 5837 6283 6887 7284 7489 7550 10329 11202 11399 12795 589 1564 1747 2960 3833 4502 7491 7746 8196 9567 9574 10187 10591 12947 804 1177 1414 3765 4745 7594 9126 9230 9251 10299 10336 11563 11844 12209

2774 2830 3918 4148 4963 5356 7125 7645 7868 8137 9119 9189 9206 12363 59 448 947 3622 5139 8115 9364 9548 9609 9750 10212 10937 11044 12668 715 1352 4538 5277 5729 6210 6418 6938 7090 7109 7386 9012 10737 11893 1583 2059 3398 3619 4277 6896 7484 7525 8284 9318 9817 10227 11636 12204 53 549 3010 5441 6090 9175 9336 9358 9839 10117 11307 11467 11507 12902 861 1054 1177 1201 1383 2538 4563 6451 6800 10540 11222 11757 12240 12732 330 1450 1798 2301 2652 3038 3187 3277 4324 4610 9395 10240 10796 11100 316 751 1226 1746 2124 2505 3497 3833 3891 7551 8696 9763 11978 12661 2677 2888 2904 3923 4804 5105 6855 7222 7893 7907 9674 10274 12683 12702 173 3397 3520 5131 5560 6666 6783 6893 7742 7842 9364 9442 12287 421 943 1893 1920 3273 4052 5758 5787 7043 11051 12141 12209 12500 679 792 2543 3243 3385 3576 4190 7501 8233 8302 9212 9522 12286 911 3651 4023 4462 4650 5336 5762 6506 8050 8381 9636 9724 12486 1373 1728 1911 4101 4913 5003 6859 7137 8035 9056 9378 9937 10184 515 2357 2779 2797 3163 3845 3976 6969 7704 9104 10102 11507 12700 270 1744 1804 3432 3782 4643 5946 6279 6549 7064 7393 11659 12002 261 1517 2269 3554 4762 5103 5460 6429 6464 8962 9651 10927 12268 782 1217 1395 2383 5754 6060 6540 7109 7286 7438 7846 9488 10119 2070 2247 2589 2644 3270 3875 4901 6475 8953 10090 10629 12496 12547 863 1190 1609 2971 3564 4148 5123 5262 6301 7797 7804 9517 11408 449 488 865 3549 3939 4410 4500 5700 7120 8778 9223 11660 12021 1107 1408 1883 2752 3818 4714 5979 6485 7314 7821 11290 11472 12325 713 2492 2507 2641 3576 4711 5021 5831 7334 8362 9094 9690 10778 1487 2344 5035 5336 5727 6495 9009 9345 11090 11261 11314 12383 12944 1038 1463 1472 2944 3202 5742 5793 6972 7853 8919 9808 10549 12619 134 957 2018 2140 2629 3884 5821 7319 8676 10305 10670 12031 12588 5294 9842 4396 6648 2863 5308 10467 11711 3412 6909 450 3919 5639 9801 298 4323 397 10223 4424 9051 2038 2376 5889 11321 12500 3590 4081 12684 3485 4016 9826 6 2869 8310 5983 9818 10877 2282 9346 11477 4931 6135 10473 300 2901 9937 3185 5215 7479 472 5845 5915 2476 7687 11934 3279 8782 11527 4350 7138 7144 7454 7818 8253 1391 8717 8844 1940 4736 10556 5471 7344 8089 9157 10640 11919 1343 5402 12724 2581 4118 8142 5165 9328 11386 7222 7262 12955 6711 11224 11737 401 3195 11940 6114 6969 8208 1402 7917 9738 965 7700 10139 3428 5767 12000 3501 7052 8803 1447 10504 10961 1870 1914 7762 613 2063 10520 3561 6480 10466 3389 3887 10110 995 1104 1640 1492 4122 7572 3243 9765 12415 7297 11200 11533 1959 10325 11306 1675 5313 11475 3621 4658 12790 4208 5650 8687 2467 7691 11886 3039 3190 5017 866 1375 2272 4374 6453 8228 2763 4668 4749 640 1346 6924 6588 6983 10075 3389 9260 12508 89 5799 9973 1290 2978 8038 317 742 8017 5378 5618 6586 3369 3827 4536 1000 10436 12288 3762 11384 11897 848 874 8968 1001 4751 12066 1788 6685 12397 5721 8247 9005 649 7547 9837 2263 9415 10862 3954 4111 7767 952 4393 5523 8132 8580 10906 4191 9677 12585 1071 10601 11106 3069 6943 11015 5555 8088 9537 85 2810 3100 1249 8418 8684 2743 12099 12686 2908 3691 9890 10172 10409 11615 8358 10584 12082 4902 6310 8368 4976 10047 11299 7325 8228 11092 4942 6974 8533 5782 9780 9869 15 4728 10395 369 1900 11517 3796 7434 9085 2473 9813 12636 1472 3557 6607 174 3715 4811 6263 6694 8114 4538 6635 9101 3199 8348 10057 6176 7498 7937 1837 3382 5688 8897 11342 11680 455 6465 7428 1900 3666 8968 3481 6308 10199 159 2654 12150 5602 6695 12897 3309 4899 6415 6 99 7615 1722 6386 11112 5090 8873 10718 4164 6731 12121 367 846 7678 222 6050 12711 3154 7149 7557 1556 4667 7990 2536 9712 9932 4104 7040 9983 6365 11604 12457 3393 10323 10743 724 2237 5455 108 1705 6151.

In the first transmission method according to the present technology, the LDPC encoding is performed on the basis of the check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 3/16, and the group-wise interleaving of interleaving the LDPC code in units of a bit group of 360 bits is performed. Then, the LDPC code is mapped to any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits. In the group-wise interleaving, the (i+1)-th bit group from the lead of the LDPC code is set as a bit group i, and the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into the arrangement of the bit group

138, 38, 106, 76, 172, 27, 150, 95, 44, 187, 64, 18, 28, 98, 180, 101, 149, 146, 126, 26, 93, 178, 186, 70, 104, 131, 19, 45, 102, 122, 152, 66, 63, 173, 9, 55, 25, 1, 154, 85, 5, 51, 43, 82, 86, 151, 148, 48, 190, 179, 62, 60, 94, 174, 142, 39, 169, 170, 47, 125, 33, 128, 162, 2, 129, 57, 79, 118, 114, 69, 78, 167, 11, 136, 99, 155, 90, 21, 119, 10, 52, 91, 115, 185, 6, 110, 88, 96, 181, 143, 0, 160, 124, 130, 183, 71, 121, 182, 68, 191, 3, 32, 40, 189, 41, 156, 35, 159, 58, 89, 29, 67, 17, 109, 30, 111, 12, 46, 65, 177, 53, 77, 74, 56, 184, 15, 141, 135, 54, 163, 14, 145, 139, 134, 59, 147, 87, 107, 7, 61, 36, 113, 103, 188, 24, 165, 137, 22, 42, 49, 83, 73, 50, 161, 20, 166, 127, 157, 108, 171, 37, 72, 176, 112, 123, 144, 34, 175, 168, 117, 80, 81, 8, 31, 133, 92, 164, 132, 97, 158, 84, 100, 140, 16, 105, 23, 75, 13, 153, 116, 4, 120.

The check matrix initial value table defining the check matrix is as described above.

In the first reception device according to the present technology, the arrangement of the LDPC code after the group-wise interleaving obtained from the data transmitted from the transmission device that performs the first transmission method is returned to the original arrangement.

In the second transmission method according to the present technology, the LDPC encoding is performed on the basis of the check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 5/16, and the group-wise interleaving of interleaving the LDPC code in units of a bit group of 360 bits is performed. Then, the LDPC code is mapped to any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits. In the group-wise interleaving, the (i+1)-th bit group from the lead of the LDPC code is set as a bit group i, and the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into the arrangement of the bit group

37, 136, 161, 62, 163, 129, 160, 73, 76, 66, 34, 162, 122, 5, 87, 94, 50, 105, 132, 32, 121, 47, 74, 189, 110, 45, 75, 175, 17, 29, 108, 191, 1, 153, 20, 113, 61, 42, 51, 2, 165, 124, 43, 186, 40, 86, 168, 180, 155, 16, 93, 26, 166, 119, 159, 56, 12, 44, 46, 143, 49, 25, 176, 158, 92, 147, 54, 172, 182, 64, 157, 112, 38, 39, 11, 6, 127, 48, 151, 82, 4, 36, 183, 88, 126, 117, 111, 188, 138, 65, 70, 170, 133, 137, 146, 128, 114, 148, 141, 125, 10, 41, 116, 33, 99, 81, 187, 130, 131, 107, 60, 90, 173, 13, 71, 15, 106, 3, 149, 154, 181, 174, 190, 27, 177, 18, 21, 22, 83, 91, 150, 14, 96, 53, 0, 145, 67, 68, 144, 184, 59, 23, 118, 115, 135, 55, 134, 102, 8, 169, 85, 156, 97, 63, 104, 95, 52, 98, 139, 24, 78, 179, 19, 28, 69, 58, 109, 57, 164, 31, 84, 140, 103, 77, 123, 171, 72, 79, 152, 35, 80, 7, 185, 167, 9, 100, 142, 89, 30, 120, 178, 101.

The check matrix initial value table defining the check matrix is as described above.

In the second reception device according to the present technology, the arrangement of the LDPC code after the group-wise interleaving obtained from the data transmitted from the transmission device that performs the second transmission method is returned to the original arrangement.

In the third transmission method according to the present technology, the LDPC encoding is performed on the basis of the check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 7/16, and the group-wise interleaving of interleaving the LDPC code in units of a bit group of 360 bits is performed. Then, the LDPC code is mapped to any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits. In the group-wise interleaving, the (i+1)-th bit group from the lead of the LDPC code is set as a bit group i, and the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into the arrangement of the bit group

148, 189, 3, 121, 80, 135, 7, 96, 46, 109, 190, 111, 118, 23, 5, 149, 19, 140, 106, 36, 161, 71, 6, 176, 160, 76, 8, 168, 171, 173, 40, 37, 25, 50, 164, 108, 139, 31, 127, 142, 163, 177, 24, 20, 157, 83, 116, 42, 73, 69, 88, 184, 147, 136, 187, 49, 45, 35, 170, 62, 63, 181, 117, 123, 122, 72, 55, 53, 133, 159, 94, 175, 179, 158, 97, 93, 13, 130, 144, 81, 68, 2, 64, 155, 119, 43, 143, 1, 112, 18, 146, 172, 132, 191, 134, 61, 138, 9, 178, 103, 15, 47, 154, 17, 152, 153, 107, 115, 39, 166, 33, 104, 56, 52, 60, 131, 141, 78, 186, 162, 54, 0, 85, 12, 86, 77, 126, 34, 180, 10, 87, 38, 4, 26, 79, 27, 98, 66, 75, 67, 110, 101, 128, 16, 22, 28, 151, 21, 99, 74, 11, 100, 65, 58, 150, 145, 14, 59, 102, 51, 48, 113, 92, 167, 188, 174, 156, 114, 82, 125, 124, 70, 137, 90, 30, 44, 57, 105, 95, 165, 29, 89, 41, 169, 120, 91, 32, 183, 129, 182, 185, 84.

The check matrix initial value table defining the check matrix is as described above.

In the third reception device according to the present technology, the arrangement of the LDPC code after the group-wise interleaving obtained from the data transmitted from the transmission device that performs the third transmission method is returned to the original arrangement.

In the fourth transmission method according to the present technology, the LDPC encoding is performed on the basis of the check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 9/16, and the group-wise interleaving of interleaving the LDPC code in units of a bit group of 360 bits is performed. Then, the LDPC code is mapped to any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits. In the group-wise interleaving, the (i+1)-th bit group from the lead of the LDPC code is set as a bit group i, and the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into the arrangement of the bit group

67, 20, 9, 75, 143, 94, 144, 122, 56, 88, 180, 72, 102, 100, 113, 157, 170, 59, 128, 162, 26, 38, 61, 156, 115, 117, 190, 77, 22, 74, 119, 12, 8, 179, 182, 85, 188, 191, 154, 41, 58, 142, 186, 107, 73, 189, 15, 130, 127, 160, 55, 19, 45, 137, 124, 133, 146, 43, 60, 183, 153, 177, 123, 181, 95, 49, 140, 4, 51, 3, 21, 164, 83, 187, 148, 11, 168, 149, 92, 65, 30, 90, 23, 116, 57, 161, 125, 175, 129, 126, 97, 14, 96, 66, 37, 178, 64, 173, 184, 80, 101, 34, 81, 131, 76, 147, 47, 135, 111, 121, 44, 68, 98, 48, 120, 40, 87, 176, 104, 106, 28, 163, 52, 1, 152, 79, 42, 139, 16, 2, 71, 7, 109, 114, 112, 54, 62, 169, 35, 150, 171, 110, 50, 108, 105, 69, 118, 84, 39, 132, 63, 31, 18, 134, 103, 185, 6, 145, 24, 70, 36, 29, 5, 93, 99, 33, 82, 89, 167, 174, 27, 165, 91, 138, 155, 32, 159, 141, 136, 151, 25, 158, 86, 17, 13, 172, 53, 10, 46, 166, 0, 78.

The check matrix initial value table defining the check matrix is as described above.

In the fourth reception device according to the present technology, the arrangement of the LDPC code after the group-wise interleaving obtained from the data transmitted from the transmission device that performs the fourth transmission method is returned to the original arrangement.

In the fifth transmission method according to the present technology, the LDPC encoding is performed on the basis of the check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 11/16, and the group-wise interleaving of interleaving the LDPC code in units of a bit group of 360 bits is performed. Then, the LDPC code is mapped to any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits. In the group-wise interleaving, the (i+1)-th bit group from the lead of the LDPC code is set as a bit group i, and the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into the arrangement of the bit group

84, 126, 45, 76, 121, 91, 52, 162, 79, 187, 134, 108, 47, 16, 72, 119, 43, 107, 98, 135, 147, 110, 0, 60, 4, 61, 117, 24, 167, 65, 40, 55, 73, 112, 85, 35, 156, 95, 137, 171, 9, 11, 54, 131, 138, 157, 152, 111, 183, 161, 41, 69, 21, 94, 113, 8, 153, 39, 57, 143, 86, 12, 188, 184, 15, 30, 118, 136, 64, 169, 148, 22, 6, 68, 168, 78, 105, 101, 190, 3, 59, 124, 170, 62, 87, 46, 28, 29, 186, 2, 25, 177, 140, 53, 154, 37, 18, 189, 93, 114, 33, 1, 158, 122, 103, 5, 104, 80, 166, 34, 106, 51, 10, 180, 139, 125, 178, 100, 13, 70, 142, 185, 159, 50, 66, 102, 150, 127, 160, 92, 81, 173, 115, 144, 145, 128, 74, 88, 20, 116, 179, 96, 17, 155, 175, 75, 165, 7, 191, 149, 44, 23, 99, 48, 163, 42, 63, 164, 90, 120, 27, 31, 14, 19, 32, 174, 26, 67, 89, 97, 56, 146, 82, 133, 129, 109, 71, 58, 130, 182, 123, 176, 49, 36, 181, 38, 141, 151, 83, 77, 172, 132.

The check matrix initial value table defining the check matrix is as described above.

In the fifth reception device according to the present technology, the arrangement of the LDPC code after the group-wise interleaving obtained from the data transmitted from the transmission device that performs the fifth transmission method is returned to the original arrangement.

In the sixth transmission method according to the present technology, the LDPC encoding is performed on the basis of the check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 13/16, and the group-wise interleaving of interleaving the LDPC code in units of a bit group of 360 bits is performed. Then, the LDPC code is mapped to any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits. In the group-wise interleaving, the (i+1)-th bit group from the lead of the LDPC code is set as a bit group i, and the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into the arrangement of the bit group

30, 127, 60, 115, 80, 50, 150, 39, 176, 171, 47, 104, 70, 33, 56, 3, 10, 26, 19, 149, 153, 141, 98, 46, 64, 71, 130, 107, 94, 16, 164, 169, 57, 168, 126, 157, 133, 12, 154, 135, 35, 53, 40, 183, 28, 1, 160, 67, 163, 134, 181, 59, 99, 186, 86, 36, 178, 152, 48, 117, 44, 14, 66, 172, 17, 31, 182, 166, 187, 55, 62, 143, 69, 77, 9, 113, 158, 91, 189, 84, 151, 74, 45, 97, 122, 114, 75, 41, 162, 90, 110, 106, 116, 131, 129, 188, 92, 11, 147, 108, 20, 159, 146, 51, 29, 109, 89, 6, 96, 155, 43, 111, 138, 85, 119, 5, 22, 105, 170, 4, 15, 148, 145, 63, 0, 156, 81, 68, 13, 137, 79, 103, 2, 179, 38, 180, 132, 123, 144, 167, 140, 174, 49, 37, 82, 128, 101, 21, 124, 177, 121, 8, 23, 136, 42, 27, 139, 72, 185, 18, 65, 161, 7, 125, 88, 34, 73, 184, 52, 190, 120, 102, 100, 87, 95, 118, 83, 112, 175, 78, 58, 24, 165, 54, 61, 25, 191, 76, 142, 93, 173, 32.

The check matrix initial value table defining the check matrix is as described above.

In the sixth reception device according to the present technology, the arrangement of the LDPC code after the group-wise interleaving obtained from the data transmitted from the transmission device that performs the sixth transmission method is returned to the original arrangement.

Note that the reception device may be an independent device or an internal block constituting one device.

Effects of the Invention

According to the present technology, it is possible to ensure good communication quality in data transmission using an LDPC code.

In addition, the effects described herein are not necessarily limited and may be any effects to be described in the present disclosure.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a diagram illustrating a check matrix H of an LDPC code.

FIG. 2 is a flowchart illustrating a decoding procedure of an LDPC code.

FIG. 3 is a diagram illustrating an example of a check matrix of an LDPC code.

FIG. 4 is a diagram illustrating an example of a Tanner graph of a check matrix.

FIG. 5 is a diagram illustrating an example of a variable node.

FIG. 6 is a diagram illustrating an example of a check node.

FIG. 7 is a diagram illustrating a configuration example of an embodiment of a transmission system to which the present technology is applied.

FIG. 8 is a block diagram illustrating a configuration example of a transmission device 11.

FIG. 9 is a block diagram illustrating a configuration example of a bit interleaver 116.

FIG. 10 is a diagram illustrating an example of a check matrix.

FIG. 11 is a diagram illustrating an example of a parity matrix.

FIG. 12 is a diagram illustrating a check matrix of an LDPC code defined in the DVB-T.2 standard.

FIG. 13 is a diagram illustrating a check matrix of an LDPC code defined in the DVB-T.2 standard.

FIG. 14 is a diagram illustrating an example of a Tanner graph for decoding of an LDPC code.

FIGS. 15A and 15B are diagrams illustrating an example of a parity matrix HT having a staircase structure and a Tanner graph corresponding to the parity matrix HT.

FIG. 16 is a diagram illustrating an example of a parity matrix HT of a check matrix H corresponding to an LDPC code after parity interleaving.

FIG. 17 is a flowchart illustrating an example of processing performed by a bit interleaver 116 and a mapper 117.

FIG. 18 is a block diagram illustrating a configuration example of an LDPC encoder 115.

FIG. 19 is a flowchart illustrating an example of processing of an LDPC encoder 115.

FIG. 20 is a diagram illustrating an example of a check matrix initial value table with an encoding rate of 1/4 and a code length of 16200.

FIG. 21 is a diagram illustrating a method of obtaining a check matrix H from a check matrix initial value table.

FIG. 22 is a diagram illustrating a structure of a check matrix.

FIG. 23 is a diagram illustrating an example of a check matrix initial value table.

FIG. 24 is a diagram illustrating an A matrix generated from a check matrix initial value table;

FIG. 25 is a diagram illustrating parity interleaving of a B matrix.

FIG. 26 is a diagram illustrating a C matrix generated from a check matrix initial value table;

FIG. 27 illustrates parity interleaving of a D matrix.

FIG. 28 is a diagram illustrating a check matrix in which column permutation is performed as parity deinterleaving to return parity interleaving to original parity interleaving.

FIG. 29 is a diagram illustrating a transformed check matrix obtained by performing row permutation on a check matrix.

FIG. 30 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=2/16 with N=69120 bits.

FIG. 31 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=3/16 with N=69120 bits.

FIG. 32 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=3/16 with N=69120 bits.

FIG. 33 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=4/16 with N=69120 bits.

FIG. 34 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=5/16 with N=69120 bits.

FIG. 35 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=5/16 with N=69120 bits.

FIG. 36 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=6/16 with N=69120 bits.

FIG. 37 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=6/16 with N=69120 bits.

FIG. 38 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=7/16 with N=69120 bits.

FIG. 39 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=7/16 with N=69120 bits.

FIG. 40 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=8/16 with N=69120 bits.

FIG. 41 is a diagram illustrating an example of a check matrix initial value table of a type-A code with r=8/16 with N=69120 bits.

FIG. 42 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=7/16 with N=69120 bits.

FIG. 43 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=7/16 with N=69120 bits.

FIG. 44 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=7/16 with N=69120 bits.

FIG. 45 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=7/16 with N=69120 bits.

FIG. 46 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=8/16 with N=69120 bits.

FIG. 47 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=8/16 with N=69120 bits.

FIG. 48 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=8/16, where N=69120 bits.

FIG. 49 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=8/16, where N=69120 bits.

FIG. 50 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=9/16 with N=69120 bits.

FIG. 51 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=9/16 with N=69120 bits.

FIG. 52 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=9/16 with N=69120 bits.

FIG. 53 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=9/16, where N=69120 bits.

FIG. 54 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=9/16, where N=69120 bits.

FIG. 55 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=9/16 with N=69120 bits.

FIG. 56 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=10/16 with N=69120 bits.

FIG. 57 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=10/16 with N=69120 bits.

FIG. 58 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=10/16 with N=69120 bits.

FIG. 59 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=10/16 with N=69120 bits.

FIG. 60 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=10/16, where N=69120 bits.

FIG. 61 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=10/16 with N=69120 bits.

FIG. 62 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=11/16 and N=69120 bits.

FIG. 63 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=11/16 and N=69120 bits.

FIG. 64 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=11/16 and N=69120 bits.

FIG. 65 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=11/16 and N=69120 bits.

FIG. 66 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=11/16 and N=69120 bits.

FIG. 67 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=11/16 and N=69120 bits.

FIG. 68 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=12/16 with N=69120 bits.

FIG. 69 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=12/16 with N=69120 bits.

FIG. 70 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=12/16 with N=69120 bits.

FIG. 71 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=12/16 with N=69120 bits.

FIG. 72 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=12/16 with N=69120 bits.

FIG. 73 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=12/16 with N=69120 bits.

FIG. 74 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=13/16 with N=69120 bits.

FIG. 75 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=13/16 with N=69120 bits.

FIG. 76 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=13/16 with N=69120 bits.

FIG. 77 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=13/16 with N=69120 bits.

FIG. 78 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=13/16 with N=69120 bits.

FIG. 79 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=13/16 with N=69120 bits.

FIG. 80 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=14/16 with N=69120 bits.

FIG. 81 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=14/16 with N=69120 bits.

FIG. 82 is a diagram illustrating an example of a check matrix initial value table of a type-B code with r=14/16 with N=69120 bits.

FIG. 83 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=14/16 with N=69120 bits.

FIG. 84 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=14/16 with N=69120 bits.

FIG. 85 is a diagram illustrating another example of a check matrix initial value table of a type-B code with r=14/16 with N=69120 bits.

FIG. 86 is a diagram illustrating an example of a Tanner graph of an ensemble of a degree sequence with a column weight of 3 and a row weight of 6;

FIG. 87 is a diagram illustrating an example of a Tanner graph of a multi-edge type ensemble.

FIG. 88 is a diagram illustrating a check matrix of a type-A scheme.

FIG. 89 is a diagram illustrating a check matrix of a type-A scheme.

FIG. 90 is a diagram illustrating a check matrix of a type-B scheme.

FIG. 91 is a diagram illustrating a check matrix of a type-B scheme.

FIG. 92 is a diagram illustrating an example of coordinates of a signal point of UC in a case where the modulation scheme is QPSK.

FIG. 93 is a diagram illustrating an example of coordinates of 2D-NUC signal points in a case where the modulation scheme is 16QAM.

FIG. 94 is a diagram illustrating an example of coordinates of a signal point of 1D-NUC in a case where the modulation scheme is 1024QAM.

FIGS. 95A and 95B are diagrams illustrating a relationship between a symbol y and a position vector u of 1024QAM.

FIG. 96 is a diagram illustrating an example of coordinates z_(q) of a signal point of QPSK-UC.

FIG. 97 is a diagram illustrating an example of coordinates z_(q) of a signal point of QPSK-UC.

FIG. 98 is a diagram illustrating an example of coordinates z_(q) of a signal point of 16QAM-UC.

FIG. 99 is a diagram illustrating an example of coordinates z_(q) of a signal point of 16QAM-UC.

FIG. 100 is a diagram illustrating an example of coordinates z_(q) of a signal point of 64QAM-UC.

FIG. 101 is a diagram illustrating an example of coordinates z_(q) of a signal point of 64QAM-UC.

FIG. 102 is a diagram illustrating an example of coordinates z_(q) of a signal point of 256QAM-UC.

FIG. 103 is a diagram illustrating an example of coordinates z_(q) of a signal point of 256QAM-UC.

FIG. 104 is a diagram illustrating an example of coordinates z_(q) of a signal point of 1024QAM-UC.

FIG. 105 is a diagram illustrating an example of coordinates z_(q) of a signal point of 1024QAM-UC.

FIG. 106 is a diagram illustrating an example of coordinates z_(q) of a signal point of 4096QAM-UC.

FIG. 107 is a diagram illustrating an example of coordinates z_(q) of a signal point of 4096QAM-UC.

FIG. 108 is a diagram illustrating an example of coordinates z_(s) of a signal point of 16QAM-2D-NUC.

FIG. 109 is a diagram illustrating an example of coordinates z_(s) of a signal point of 64QAM-2D-NUC.

FIG. 110 is a diagram illustrating an example of coordinates z_(s) of a signal point of 256QAM-2D-NUC.

FIG. 111 is a diagram illustrating an example of coordinates z_(s) of a signal point of 256QAM-2D-NUC.

FIG. 112 is a diagram illustrating an example of coordinates z_(s) of a signal point of 1024QAM-1D-NUC.

FIGS. 113A and 113B are diagrams illustrating a relationship between a symbol y of 1024QAM and a position vector u.

FIG. 114 is a diagram illustrating an example of coordinates z_(s) of a signal point of 4096QAM-1D-NUC.

FIG. 115 is a diagram illustrating a relationship between a symbol y and a position vector u of 4096QAM.

FIG. 116 is a diagram illustrating a relationship between a symbol y and a position vector u of 4096QAM.

FIG. 117 is a diagram illustrating block interleaving performed by a block interleaver 25.

FIG. 118 is a diagram illustrating block interleaving performed by the block interleaver 25.

FIG. 119 is a diagram illustrating group-wise interleaving performed by a group-wise interleaver 24.

FIG. 120 is a diagram illustrating Example 1 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 121 is a diagram illustrating Example 2 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 122 is a diagram illustrating Example 3 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 123 is a diagram illustrating Example 4 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 124 is a diagram illustrating Example 5 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 125 is a diagram illustrating Example 6 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 126 is a diagram illustrating Example 7 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 127 is a diagram illustrating Example 8 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 128 is a diagram illustrating Example 9 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 129 is a diagram illustrating Example 10 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 130 is a diagram illustrating Example 11 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 131 is a diagram illustrating Example 12 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 132 is a diagram illustrating Example 13 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 133 is a diagram illustrating Example 14 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 134 is a diagram illustrating Example 15 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 135 is a diagram illustrating Example 16 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 136 is a diagram illustrating Example 17 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 137 is a diagram illustrating Example 18 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 138 is a diagram illustrating Example 19 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 139 is a diagram illustrating Example 20 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 140 is a diagram illustrating Example 21 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 141 is a diagram illustrating Example 22 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 142 is a diagram illustrating Example 23 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 143 is a diagram illustrating Example 24 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 144 is a diagram illustrating Example 25 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 145 is a diagram illustrating Example 26 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 146 is a diagram illustrating Example 27 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 147 is a diagram illustrating Example 28 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 148 is a diagram illustrating Example 29 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 149 is a diagram illustrating Example 30 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 150 is a diagram illustrating Example 31 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 151 is a diagram illustrating Example 32 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 152 is a diagram illustrating Example 33 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 153 is a diagram illustrating Example 34 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 154 is a diagram illustrating Example 35 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 155 is a diagram illustrating Example 36 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 156 is a diagram illustrating Example 37 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 157 is a diagram illustrating Example 38 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 158 is a diagram illustrating Example 39 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 159 is a diagram illustrating Example 40 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 160 is a diagram illustrating Example 41 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 161 is a diagram illustrating Example 42 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 162 is a diagram illustrating Example 43 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 163 is a diagram illustrating Example 44 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 164 is a diagram illustrating Example 45 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 165 is a diagram illustrating Example 46 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 166 is a diagram illustrating Example 47 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 167 is a diagram illustrating Example 48 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 168 is a diagram illustrating Example 49 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 169 is a diagram illustrating Example 50 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 170 is a diagram illustrating Example 51 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 171 is a diagram illustrating Example 52 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 172 is a diagram illustrating Example 53 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 173 is a diagram illustrating Example 54 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 174 is a diagram illustrating Example 55 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 175 is a diagram illustrating Example 56 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 176 is a diagram illustrating Example 57 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 177 is a diagram illustrating Example 58 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 178 is a diagram illustrating Example 59 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 179 is a diagram illustrating Example 60 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 180 is a diagram illustrating Example 61 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 181 is a diagram illustrating Example 62 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 182 is a diagram illustrating Example 63 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 183 is a diagram illustrating Example 64 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 184 is a diagram illustrating Example 65 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 185 is a diagram illustrating Example 66 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 186 is a diagram illustrating Example 67 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 187 is a diagram illustrating Example 68 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 188 is a diagram illustrating Example 69 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 189 is a diagram illustrating Example 70 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 190 is a diagram illustrating Example 71 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 191 is a diagram illustrating Example 72 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 192 is a diagram illustrating Example 73 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 193 is a diagram illustrating Example 74 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 194 is a diagram illustrating Example 75 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 195 is a diagram illustrating Example 76 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 196 is a diagram illustrating Example 77 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 197 is a diagram illustrating Example 78 of a GW pattern for an LDPC code with a code length N of 69120 bits.

FIG. 198 is a block diagram illustrating a configuration example of a reception device 12.

FIG. 199 is a block diagram illustrating a configuration example of a bit deinterleaver 165.

FIG. 200 is a flowchart illustrating an example of processing performed by a demapper 164, a bit deinterleaver 165, and an LDPC decoder 166.

FIG. 201 is a diagram illustrating an example of a check matrix of an LDPC code.

FIG. 202 is a diagram illustrating an example of a matrix (transformed check matrix) obtained by performing row permutation and column permutation on a check matrix.

FIG. 203 is a diagram illustrating an example of a transformed check matrix divided into 5×5 units.

FIG. 204 is a block diagram illustrating a configuration example of a decoding device that performs P node operations collectively.

FIG. 205 is a block diagram illustrating a configuration example of an LDPC decoder 166.

FIG. 206 is a diagram illustrating lock deinterleaving performed by a block deinterleaver 54.

FIG. 207 is a block diagram illustrating another configuration example of a bit deinterleaver 165.

FIG. 208 is a block diagram illustrating a first configuration example of a reception system to which a reception device 12 can be applied.

FIG. 209 is a block diagram illustrating a second configuration example of a reception system to which a reception device 12 can be applied.

FIG. 210 is a block diagram illustrating a third configuration example of a reception system to which a reception device 12 can be applied.

FIG. 211 is a block diagram illustrating a configuration example of an embodiment of a computer to which the present technology is applied.

MODE FOR CARRYING OUT THE INVENTION

Hereinafter, before embodiments of the present technology are described, an LDPC code will be described.

<LDPC Code>

Note that, although the LDPC code is a linear code and needs not to be binary, the LDPC code will be described herein as binary.

An LDPC code is most characterized in that a parity check matrix defining the LDPC code is sparse. Herein, a sparse matrix is a matrix of which the number of 1's of matrix elements is very small (a matrix of which most elements are 0).

FIG. 1 is a diagram illustrating an example of a check matrix H of an LDPC code.

In the check matrix H of FIG. 1, the weight (column weight) (number of 1's) of each column is “3”, and the weight (row weight) of each row is “6”.

In encoding (LDPC encoding) with an LDPC code, a code word (LDPC code) is generated, for example, by generating a generation matrix G on the basis of the check matrix H and multiplying the generation matrix G with binary information bits.

Specifically, the encoding device that performs the LDPC encoding first calculates a generation matrix G which satisfies the formula GH^(T)=0 between the generation matrix G and the transposed matrix H^(T) of the check matrix H. Herein, in a case where the generation matrix G is a K×N matrix, the encoding device multiplies the generation matrix G by a bit string (vector u) of information bits including K bits to generate a code word c (=uG) including N bits. The code word (LDPC code) generated by the encoding device is received at the reception side via a predetermined communication line.

The decoding of the LDPC code is an algorithm, referred to as probabilistic decoding, proposed by Gallager and can be performed by a message passing algorithm with probabilistic propagation (belief propagation) on a so-called Tanner graph including a variable node (also called a message node) and a check node. Herein, hereinafter, as appropriate, the variable node and the check node are also simply referred to as nodes.

FIG. 2 is a flowchart illustrating a procedure of the decoding of the LDPC code.

In addition, hereinafter, as appropriate, a real value (received LLR) represented by “0” likeliness of the value of the i-th code bit of the LDPC code (1 code word) received by the reception side in a log likelihood ratio is also referred to as a reception value u_(0i). In addition, a message output from the check node is denoted by u_(j), and a message output from the variable node is denoted by v_(i).

First, in the decoding of the LDPC code, as illustrated in FIG. 2, an LDPC code is received in step S11, and a message (check node message) u_(j) is reset to “0”, and a variable k which has an integer as a counter for repeated processing is reset to “0”. Then, the process proceeds to step S12. In step S12, on the basis of the reception value u_(0i) obtained by receiving the LDPC code, a message (variable node message) v_(i) is obtained by performing an operation (variable node operation) expressed by Formula (1), and in addition, on the basis of the message v_(i), a message u_(j) is obtained by performing an operation (check node operation) expressed by Formula (2).

$\begin{matrix} \left\lbrack {{Formula}\mspace{14mu} 1} \right\rbrack & \; \\ {v_{i} = {u_{0\; i} + {\sum\limits_{j = 1}^{d_{v} - 1}u_{j}}}} & (1) \\ \left\lbrack {{Formula}\mspace{14mu} 2} \right\rbrack & \; \\ {{\tanh\left( \frac{u_{j}}{2} \right)} = {\prod\limits_{i = 1}^{d_{c} - 1}{\tanh\left( \frac{v_{i}}{2} \right)}}} & (2) \end{matrix}$

Herein, d_(v) and d_(c) in Formula (1) and Formula (2) are parameters that can be arbitrarily selected to indicate the number of “1s” in the vertical direction (column) and the horizontal direction (row) of the check matrix H, respectively. For example, in the case of an LDPC code ((3, 6) LDPC code) for a check matrix H with a column weight of 3 and a row weight of 6 as illustrated in FIG. 1, d_(v)=3 and d_(c)=6.

In addition, in each of the variable node operation of Formula (1) and the check node operation of Formula (2), since a message input from a branch (edge) (a line connecting a variable node and a check node) which is to output the message is not a target of operation, the range of the operation is 1 to d_(v)-1 or 1 to d_(c)-1. In addition, actually, a table of a function R(v₁, v₂) expressed by Formula (3) defined by one output for two inputs v₁ and v₂ is generated in advance, and the check node operation of Formula (2) is performed by using the table continuously (recursively) as expressed by Formula (4). [Formula 3] x=2 tan h ⁻¹{tan h(v ₁/2)tan h(v ₂/2)}=R(v ₁ ,v ₂)  (3) [Formula 4] u _(j) =R(v ₁ ,R(v ₂ ,R(v ₃ , . . . R(v _(d) _(c) ₋₂ ,v _(d) _(c) ₋))))  (4)

In step S12, furthermore, the variable k is incremented by “1”, and the process proceeds to step S13. In step S13, it is determined whether or not the variable k is larger than a predetermined number C of times of repetition of the decoding. In a case where it is determined in step S13 that the variable k is not larger than C, the process returns to step S12, and similar processing is repeated.

In addition, in a case where it is determined in step S13 that the variable k is larger than C, the process proceeds to step S14, and a message v_(i) as a decoding result to be finally output is obtained and output by performing the operation expressed by Formula (5). The decoding process of the LDPC code is ended.

$\begin{matrix} \left\lbrack {{Formula}\mspace{14mu} 5} \right\rbrack & \; \\ {v_{i} = {u_{0\; i} + {\sum\limits_{j = 1}^{d_{v}}u_{j}}}} & (5) \end{matrix}$

Herein, unlike the variable node operation of Formula (1), the operation of Formula (5) is performed by using messages u_(j) from all the branches connected to the variable node.

FIG. 3 is a diagram illustrating an example of a check matrix H of a (3, 6) LDPC code (an encoding rate of 1/2 and a code length of 12).

In the check matrix H of FIG. 3, similarly to FIG. 1, the column weight is 3 and the row weight is 6.

FIG. 4 is a diagram illustrating a Tanner graph of the check matrix H of FIG. 3.

Herein, in FIG. 4, a check node is indicated by plus “+”, and a variable node is indicated by equal “=”. The check nodes and variable nodes correspond to the rows and columns of the check matrix H, respectively. The connection between the check node and the variable node is a branch (edge) and corresponds to “1” of an element of the check matrix.

That is, in a case where the element of the j-th row and the i-th column of the check matrix is 1, in FIG. 4, the i-th variable node (“=” node) from the top and the j-th check node (“+” node) from the top are connected by branches. The branch indicates that the code bit corresponding to the variable node has a constraint corresponding to the check node.

In a sum product algorithm which is a decoding method of an LDPC code, a variable node operation and a check node operation are repeatedly performed.

FIG. 5 is a diagram illustrating the variable node operation performed by the variable node.

In the variable node, a message v_(i) corresponding to the branch to be calculated is obtained by the variable node operation of Formula (1) using messages u₁ and u₂ from the remaining branches connected to the variable node and a reception value u_(0i). The messages corresponding to the other branches are obtained in a similar manner.

FIG. 6 is a diagram illustrating a check node operation performed by the check node.

Herein, the check node operation of Formula (2) can be written as Formula (6) by using the relationship of the formula a×b=exp{ln (|a|)+ln (|b|)}×sign (a)×sign (b). However, sign (x) is 1 when x≥0, and −1 when x<0.

$\begin{matrix} {\mspace{79mu}\left\lbrack {{Formula}\mspace{14mu} 6} \right\rbrack} & \; \\ \begin{matrix} {u_{j} = {2\;{\tanh^{- 1}\left( {\prod\limits_{i = 1}^{d_{c} - 1}{\tanh\left( \frac{v_{i}}{2} \right)}} \right)}}} \\ {= {2\;{\tanh^{- 1}\left\lbrack {\exp\left\{ {\sum\limits_{i = 1}^{d_{c} - 1}{{- \ln}\;\left( {{\tanh\left( \frac{v_{i}}{2} \right)}} \right)}} \right\} \times {\prod\limits_{i = 1}^{d_{c} - 1}{{sign}\left( {\tanh\left( \frac{v_{i}}{2} \right)} \right)}}} \right\rbrack}}} \\ {= {2{\tanh^{- 1}\left\lbrack {\exp\left\{ {- \left( {\sum\limits_{i = 1}^{d_{c} - 1}{{- \ln}\;\left( {\tanh\left( \frac{v_{i}}{2} \right)} \right)}} \right)} \right\}} \right\rbrack} \times {\prod\limits_{i = 1}^{d_{c} - 1}{{sign}\left( v_{i} \right)}}}} \end{matrix} & (6) \end{matrix}$

When x≥0, if the function ϕ(x) is defined as the formula ϕ (x)=ln(tan h(x/2)), the formula ϕ⁻¹(x)=2 tan h⁻¹(e^(−x)) is satisfied, and thus, Formula (6) can be transformed into Formula (7).

$\begin{matrix} \left\lbrack {{Formula}\mspace{14mu} 7} \right\rbrack & \; \\ {u_{j} = {{\phi^{- 1}\left( {\sum\limits_{i = 1}^{d_{c} - 1}{\phi\left( {v_{i}} \right)}} \right)} \times {\prod\limits_{i = 1}^{d_{c} - 1}{{sign}\left( v_{i} \right)}}}} & (7) \end{matrix}$

In the check node, the check node operation of Formula (2) is performed according to Formula (7).

That is, in the check node, as illustrated in FIG. 6, the message u_(j) corresponding to the branch to be calculated can be obtained by the check node operation of Formula (7) using messages v₁, v₂, v₃, v₄, and v₅ from the remaining branches connected to the check node. The messages corresponding to the other branches are obtained in a similar manner.

In addition, the function ϕ(x) of Formula (7) can be expressed by the formula ϕ(x)=ln((e^(x)+1)/(e^(x)−1)), and when x>0, ϕ (x)=ϕ⁻¹(x). When the functions ϕ(x) and ϕ⁻¹ (x) are implemented by hardware, the functions may be implemented by using a look up table (LUT), but both become the same LUT.

<Configuration Example of Transmission System to which the Present Technology is Applied>

FIG. 7 is a diagram illustrating a configuration example of an embodiment of a transmission system (herein, a system is a logical aggregation of a plurality of devices, regardless of whether or not devices of respective configurations exist in the same housing) to which the present technology is applied.

In FIG. 7, the transmission system includes a transmission device 11 and a reception device 12.

The transmission device 11 performs transmitting (broadcasting) (transferring) of, for example, a program of television broadcasting or the like. That is, the transmission device 11 encodes a target data to be transmitted, for example, an image data, an audio data, or the like as the program into an LDPC code and transmits the LDPC code via a communication line 13 such as a satellite line, a terrestrial wave line, or a cable (wired line).

The reception device 12 receives the LDPC code transmitted from the transmission device 11 via the communication line 13, decodes the LDPC code to a target data, and outputs the decoded data.

Herein, it is known that the LDPC code used in the transmission system of FIG. 7 exhibits extremely high capability in an additive white gaussian noise (AWGN) transmission line.

On the other hand, in the communication line 13, there may occur a burst error and erasure. For example, in a case where the communication line 13 is a terrestrial wave line, particularly, in an orthogonal frequency division multiplexing (OFDM) system, in a multi-path environment where a desired to undesired ratios (D/U) is 0 dB (“undesired=echo” power is equal to “desired=main path” power), the power of a specific symbol may be 0 (erasure) depending on the delay of echo (paths other than the main path).

In addition, even in a flutter (a transmission line in which a delay is 0 and an echo with Doppler frequency is added), in a case where the D/U is 0 dB, there may occur a case where the power of the entire symbol of the OFDM at a specific time may be 0 (erasure) due to the Doppler frequency.

Furthermore, there may occur a burst error due to a wiring condition from a reception unit (not illustrated) such as an antenna that receives a signal from the transmission device 11 to the reception device 12 on the side of the reception device 12 or instability of the power supply of the reception device 12.

On the other hand, in the decoding of the LDPC code, in the columns of the check matrix H and hence the variable nodes corresponding to the code bits of the LDPC code, as illustrated in FIG. 5, since the variable node operation of Formula (1) along with the addition of (the reception value u_(0i) of) the code bit of the LDPC code is performed, if an error occurs in the code bit used for the variable node operation, the accuracy of the message to be obtained is lowered.

Then, in the decoding of the LDPC code, in the check node, since the check node operation of Formula (7) is performed by using the message obtained by the variable node connected to the check node, if the number of check nodes at which a plurality of the connected variable nodes (the code bits of the LDPC code corresponding to the variable nodes) simultaneously causes errors (including erasures) is increased, the decoding performance is deteriorated.

That is, for example, if two or more of the variable nodes connected to the check node simultaneously cause erasures, a message indicating that the probability having a value of 0 and the probability having a value of 1 are equal probability is returned to the all the variable nodes. In this case, the check node returning a message indicating equal probability does not contribute to one decoding process (one set of the variable node operation and the check node operation), and as a result, it requires a large number of repetitions of the decoding process. Therefore, the decoding performance is deteriorated, and the power consumption of the reception device 12 that decodes the LDPC code is increased.

Therefore, in the transmission system of FIG. 7, it is possible to improve the resistance to burst errors and erasure while maintaining the performance in the AWGN transmission line (AWGN channel).

<Configuration Example of Transmission Device 11>

FIG. 8 is a block diagram illustrating a configuration example of the transmission device 11 of FIG. 7.

In the transmission device 11, one or more input streams as a target data are supplied to a mode adaptation/multiplexer 111.

The mode adaptation/multiplexer 111 performs processing such as mode selection and multiplexing of one or more input streams supplied to the mode adaptation/multiplexer as necessary and supplies the data obtained as a result thereof to a padder 112.

The padder 112 performs necessary zero-padding (null inserting) on the data from the mode adaptation/multiplexer 111 and supplies the data obtained as a result thereof to a BB scrambler 113.

The BB scrambler 113 performs base-band (BB) Scrambling on the data from the padder 112 and supplies the data obtained as a result thereof to a BCH encoder 114.

The BCH encoder 114 performs BCH encoding on the data from the BB scrambler 113 and supplies the data obtained as a result thereof to an LDPC encoder 115 as an LDPC target data to be subjected to LDPC encoding.

The LDPC encoder 115 performs, on the LDPC target data from the BCH encoder 114, LDPC encoding according to a check matrix or the like in which, for example, a parity matrix which is a portion corresponding to parity bits of an LDPC code has a staircase structure (dual diagonal structure) and outputs an LDPC code in which the LDPC target data is set as an information bit.

That is, the LDPC encoder 115 performs LDPC encoding to encode the LDPC target data into the LDPC code (corresponding to the check matrix) defined in a predetermined DVB-S.2, DVB-T.2, DVB-C.2, ATSC 3.0 standard, or the like and other LDPC codes, for example, and outputs the LDPC code obtained as a result thereof.

Herein, the LDPC code defined in the DVB-S.2 or ATSC 3.0 standard and the LDPC code to be adopted in the ATSC 3.0 standard are irregular repeat accumulate (IRA) codes, and (a portion or all of) the parity matrix in the check matrix of the LDPC code has a staircase structure. The parity matrix and the staircase structure will be described later. In addition, the IRA codes are disclosed in, for example, “Irregular Repeat-Accumulate Codes,” H. Jin, A. Khandekar, and R. J. McEliece, in Proceedings of 2nd International Symposium on Turbo codes and Related Topics, pp. 1-8, September 2000.

The LDPC code output from the LDPC encoder 115 is supplied to a bit interleaver 116.

The bit interleaver 116 performs bit interleaving described later on the LDPC code from the LDPC encoder 115 and supplies the LDPC code after the bit interleaving to a mapper 117.

The mapper 117 maps the LDPC code from the bit interleaver 116 to a signal point indicating one symbol of quadrature modulation in units of code bits of one or more bits of the LDPC code (in units of a symbol) and performs quadrature modulation (multiple value modulation).

That is, the mapper 117 performs quadrature modulation by mapping the LDPC code from the bit interleaver 116 to signal points determined in a modulation scheme, in which the quadrature modulation of the LDPC code is to be performed, on a constellation which is an IQ plane defined by an I-axis indicating an I component in phase with the carrier wave and a Q-axis indicating a Q component perpendicular to the carrier wave.

In a case where the number of signal points of constellation used in the modulation scheme of the quadrature modulation performed by the mapper 117 is 2^(m), in the mapper 117, the code bits of m bits of the LDPC code are used as a symbol (one symbol), and the LDPC code from the bit interleaver 116 is mapped to a signal point indicating a symbol among 2^(m) signal points in units of a symbol.

Herein, as a modulation scheme of the quadrature modulation performed by the mapper 117, for example, there may be exemplified a modulation scheme defined in the DVB-S.2 standard, the ATSC3.0 standard, or the like, other modulation schemes, that is, for example, binary phase shift keying (BPSK), quadrature phase shift keying (QPSK), 8 phase-shift keying (PSK), 16 amplitude phase-shift keying (APSK), 32APSK, 16 quadrature amplitude modulation (QAM), 64QAM, 256QAM, 1024QAM, 4096QAM, 4 pulse amplitude modulation (PAM) and the like. In the mapper 117, which modulation scheme is used to perform the quadrature modulation is set in advance, for example, in accordance with the operation of the operator of the transmission device 11 or the like.

The data (the mapping result of mapping the symbols to the signal points) obtained by the processing in the mapper 117 is supplied to a time interleaver 118.

The time interleaver 118 performs time interleaving (interleaving in the time direction) on the data from the mapper 117 in units of a symbol and supplies the data obtained as a result thereof to a single input single output/multiple input single output (SISO/MISO) encoder 119].

The SISO/MISO encoder 119 performs space-time encoding on the data from the time interleaver 118 and supplies the data to a frequency interleaver 120.

The frequency interleaver 120 performs frequency interleaving (interleaving in the frequency direction) on the data from the SISO/MISO encoder 119 in units of a symbol and supplies the data to a frame builder & resource allocation unit 131.

On the other hand, for example, control data (signaling) for transmission control such as base band (BB) signaling (BB leader) is supplied to the BCH encoder 121.

The BCH encoder 121 performs BCH encoding on the control data supplied there to the BCH encoder in a similar manner to the BCH encoder 114 and supplies the data obtained as a result thereof to the LDPC encoder 122.

The LDPC encoder 122 performs LDPC encoding on the data from the BCH encoder 121 as an LDPC target data in a similar manner to the LDPC encoder 115 and supplies the LDPC code obtained as a result thereof to the mapper 123.

Similarly to the mapper 117, the mapper 123 maps the LDPC code from the LDPC encoder 122 to a signal point indicating one symbol of quadrature modulation in units of code bits of one or more bits of the LDPC code (in units of a symbol) to per quadrature modulation and supplies the data obtained as a result thereof to frequency interleaver 124.

Similarly to the frequency interleaver 120, the frequency interleaver 124 performs frequency interleaving on the data from the mapper 123 in units of a symbol and supplies the data to the frame builder & resource allocation unit 131.

The frame builder & resource allocation unit 131 inserts symbols of pilots at necessary positions of data (symbols) from the frequency interleavers 120 and 124, configures a frame (for example, a physical layer (PL) frame, a T2 frame, a C2 frame, or the like) configured by a predetermined number of the symbols from the data (symbols) obtained as a result thereof, and supplied the frame to an OFDM generation unit (OFDM generation) 132.

The OFDM generation unit 132 generates an OFDM signal corresponding to the frame from the frame from the frame builder & resource allocation unit 131 and transmits the OFDM signal via the communication line 13 (FIG. 7).

In addition, the transmission device 11 may be configured without providing a portion of the blocks illustrated in FIG. 8 of, for example, the time interleaver 118, the SISO/MISO encoder 119, the frequency interleaver 120, the frequency interleaver 124, and the like.

<Configuration Example of Bit Interleaver 116>

FIG. 9 is a block diagram illustrating a configuration example of the bit interleaver 116 of FIG. 8.

The bit interleaver 116 has a function of interleaving data, and includes a parity interleaver 23, a group-wise interleaver 24, and a block interleaver 25.

The parity interleaver 23 performs parity interleaving in which the parity bits of the LDPC code from the LDPC encoder 115 are interleaved at the positions of other parity bits and supplies the LDPC code after the parity interleaving to the group-wise interleaver 24.

The group-wise interleaver 24 performs group-wise interleaving on the LDPC code from the parity interleaver 23 and supplies the LDPC code after the group-wise interleaving to the block interleaver 25.

Herein, in the group-wise interleaving, 360 bits of one division obtained by dividing the LDPC codes corresponding to one code in units of 360 bits which are equal to the unit size P described later from the lead thereof are set as a bit group, and the LDPC codes from the parity interleaver 23 are interleaved in units of bit groups.

As compared with the case where the group-wise interleaving is not performed, in the case where the group-wise interleaving is performed, the error rate can be improved, and as a result, good communication quality can be ensured in the data transmission.

The block interleaver 25 performs the block interleaving to demultiplex the LDPC code from the group-wise interleaver 24 and symbolizes the LDPC code corresponding to, for example, one code with m-bit symbols which is a unit of mapping to supply the symbol to the mapper 117 (FIG. 8).

Herein, in the block interleaving, with respect to a storage area where columns, of which the number is equal to the number of bits m of the symbol, as the storage area for storing a predetermined number of bits, for example, in the column (vertical) direction are arranged in the row (horizontal) direction, the LDPC code from the group-wise interleaver 24 is written in the column direction and read in the row direction, so that the LDPC code is symbolized with the m-bit symbols.

<Check Matrix of LDPC Code>

FIG. 10 is a diagram illustrating an example of a check matrix H used for LDPC encoding in the LDPC encoder 115 of FIG. 8.

The check matrix H has a low-density generation matrix (LDGM) structure and can be indicated by an information matrix H_(A) of a portion corresponding to information bits among code bits of the LDPC code and a parity matrix H_(T) corresponding to parity bits with a formula H=[H_(A)|H_(T)] (a matrix in which elements of the information matrix H_(A) are elements on the left and elements of the parity matrix H_(T) are elements on the right).

Herein, the number of bits of the information bits and the number of bits of the parity bits among the code bits of the LDPC code (one code word) of one code are referred to as an information length K and a parity length M, respectively, and the number of bits of the code bits of one LDPC code (one code word) is referred to as a code length N (=K+M).

The information length K and the parity length M for an LDPC code with a certain code length N are determined by the encoding rate. In addition, the check matrix H becomes an M×N (rows×columns) matrix (M-row N-column matrix). Then, the information matrix H_(A) becomes an M×K matrix, and the parity matrix H_(T) becomes an M×M matrix.

FIG. 11 is a diagram illustrating an example of a parity matrix H_(T) of a check matrix H used for LDPC encoding in the LDPC encoder 115 of FIG. 8.

As the parity matrix H_(T) of the check matrix H used for LDPC encoding in the LDPC encoder 115, for example, a parity matrix H_(T) similar to that of the check matrix H of the LDPC code defined in the DVB-T.2 standard or the like can be adopted.

As illustrated in FIG. 11, the parity matrix H_(T) of the check matrix H of the LDPC code defined in the DVB-T.2 standard or the like is a matrix (lower bidiagonal matrix) having a staircase structure in which the elements of 1 are arranged in a staircase shape. The row weight of the parity matrix H_(T) is 1 for the first row and 2 for all the remaining rows. In addition, the column weight is 1 for the last one column and 2 for all remaining columns.

As described above, the LDPC code of the check matrix H in which the parity matrix H_(T) has a staircase structure can be easily generated by using the check matrix H.

That is, an LDPC code (one code word) is indicated by a row vector c, and a column vector obtained by transposing the row vector is indicated as c^(T). In addition, in the row vector c which is an LDPC code, a portion of information bits is indicated by a row vector A, and a portion of parity bits is indicated by a row vector T.

In this case, the row vector c can be indicated by the row vector A as information bits and the row vector T as parity bits with a formula c=[A|T] (elements of the row vector A are elements of the left and elements of the row vector T are the elements on the right).

The check matrix H and the row vector c=[A|T] as the LDPC code need to satisfy a formula Hc^(T)=0, and in a case where the parity matrix H_(T) of the check matrix H=[H_(A)|H_(T)] has the staircase structure illustrated in FIG. 11, a row vector T as the parity bits constituting the row vector c=[A|T] satisfying the formula Hc^(T)=0 can be obtained sequentially (in order) by setting the elements of each row to 0 in order from the element of the first row of the column Hc^(T) in the formula Hc^(T)=0.

FIG. 12 is a diagram illustrating a check matrix H of an LDPC code defined in the DVB-T.2 standard or the like.

For the KX columns from the first column of the check matrix H of the LDPC code defined in the DVB-T.2 standard or the like, the column weight is X. For the subsequent K3 column, the column weight is 3. For the subsequent (M−1) column, the column weight is 2. For the last 1 column, the column weight is 1.

Herein, KX+K3+M−1+1 is equal to the code length N.

FIG. 13 is a diagram illustrating the number of columns KX, K3 and M and the column weight X for each encoding rate r of the LDPC code defined in the DVB-T.2 standard or the like.

In the DVB-T.2 standard or the like, LDPC codes with a code length N of 64800 bits and 16200 bits are defined.

Then, for the LDPC code with a code length N of 64800 bits, 11 encoding rates (nominal rate) of 1/4, 1/3, 2/5, 1/2, 3/5, 2/3, 3/4, 4/5, 5/6, 8/9, and 9/10 are defined, and for the LDPC code with a code length N of 16200 bits, 10 encoding rates of 1/4, 1/3, 2/5, 1/2, 3/5, 2/3, 3/4, 4/5, 5/6, and 8/9 are defined.

Herein, hereinafter, the code length N of 64800 bits is also referred to as 64 k bits, and the code length N of 16200 bits is also referred to as 16 k bits.

For an LDPC code, the error rate tends to be lower for code bits corresponding to columns with larger column weights of the check matrix H.

In the check matrix H defined in the DVB-T.2 standard or the like illustrated in FIGS. 12 and 13, the column weight tends to be larger at a column closer to the lead side (left side), and thus, for an LDPC code corresponding to the check matrix H, a code bit closer to the lead is invulnerable to errors (more resistant to errors), and a code bit closer to the last is more vulnerable to errors.

<Parity Interleaving>

The parity interleaving by the parity interleaver 23 of FIG. 9 will be described with reference to FIGS. 14, 15A, 15B, and 16.

FIG. 14 is a diagram illustrating an example of (a portion of) a Tanner graph of a check matrix of an LDPC code.

As illustrated in FIG. 14, if a plurality such as two of (code bits corresponding to) the variable nodes connected to the check node simultaneously causes errors such as erasures, a message indicating that the probability having a value of 0 and the probability having a value of 1 are equal probability is returned to the all the variable node connected to the check node. For this reason, if a plurality of variable nodes connected to the same check node simultaneously becomes erasures or the like, the decoding performance is deteriorated.

By the way, similarly to the LDPC code defined in the DVB-T.2 standard or the like, the LDPC code output from the LDPC encoder 115 in FIG. 8 is, for example, an IRA code, and as illustrated in FIG. 11, the parity matrix H_(T) of the check matrix H has a staircase structure.

FIGS. 15A and 15B are diagrams illustrating an example of a parity matrix HT having a staircase structure as illustrated in FIG. 11 and a Tanner graph corresponding to the parity matrix HT.

FIG. 15A illustrates an example of the parity matrix HT having a staircase structure, and FIG. 15B illustrates a Tanner graph corresponding to the parity matrix HT of FIG. 15A.

In the parity matrix H_(T) having a staircase structure, in each row, one element is adjacent (except for the first row). For this reason, in the Tanner graph of the parity matrix H_(T), two adjacent variable nodes corresponding to the column of two adjacent elements in which the value of the parity matrix H_(T) is 1 are connected to the same check node.

Therefore, when the parity bits corresponding to the above adjacent two variable nodes are simultaneously in an erroneous state due to the burst error, the erasure, or the like, since the check node connected to the two variable nodes (the variable nodes obtaining the message by using the parity bits) corresponding to the two parity bits that are in the erroneous state returns the message indicating that the probability having a value of 0 and the probability having a value of 1 are equal probability to the variable node connected to that check node, the decoding performance is deteriorated. Then, if a burst length (the number of bits of the parity bits that are continuously in an erroneous state) becomes large, the number of check nodes returning the message indicating the equal probability is increased, and thus, the decoding performance is further deteriorated.

Therefore, the parity interleaver 23 (FIG. 9) performs the parity interleaving in which the parity bits of the LDPC code from the LDPC encoder 115 are interleaved at the positions of other parity bits in order to prevent the deterioration in the decoding performance described above.

FIG. 16 is a diagram illustrating a parity matrix H_(T) of the check matrix H corresponding to the LDPC code after the parity interleaving performed by the parity interleaver 23 of FIG. 9.

Herein, the information matrix H_(A) of the check matrix H corresponding to the LDPC code output from the LDPC encoder 115 has a cyclic structure similarly to the information matrix of the check matrix H corresponding to the LDPC code defined in the DVB-T.2 standard or the like.

The cyclic structure denotes a structure in which a certain column matches a column obtained by cyclically shifting another column and also includes a structure in which for example, for each of the P columns, the positions of 1's in each row of the P columns become the positions obtained by cyclically shifting the first column of the P columns in the column direction by a predetermined value such as a value proportional to the value q obtained by dividing the parity length M. Hereinafter, the P columns in the cyclic structure are appropriately referred to as a unit size.

As the LDPC code defined in the DVB-T.2 standard or the like, there are two types of LDPC codes with a code length N of 64800 bits, 16200 bits, and the like as described with reference to FIGS. 12 and 13, and for any one of the two types of the LDPC codes, the unit size P is defined as 360, which is one of the divisors of the parity length M except for 1 and M.

In addition, the parity length M is a value other than a prime number indicated by the formula M=q×P=q×360 by using a value q that varies depending on the encoding rate. Therefore, similarly to the unit size P, the value q is also one of the divisors of the parity length M except for the divisors of 1 and M and can be obtained by dividing the parity length M by the unit size P (a product of P and q which are divisors of the parity length M becomes the parity length M).

As described above, if it is assumed that the information length is denoted by K, an integer of 0 or more and less than P is denoted by x, and an integer of 0 or more and less than q is denoted by y, the parity interleaver 23 allows the (K+qx+y+1)-th code bit among the code bits of the LDPC code of N bits to be interleaved at the position of the (K+Py+x+1)-th code bit.

Since the (K+qx+y+1)-th code bit and the (K+Py+x+1)-th code bit are the (K+1)-th and subsequent code bits, the (K+qx+y+1)-th code bit and the (K+Py+x+1)-th code bit are both parity bits, and thus, according to the interleaving, the positions of the parity bits of the LDPC code are moved.

According to such parity interleaving, since (the parity bits corresponding to) the variable nodes connected to the same check node are separated by a unit size P, that is, 360 bits herein, in a case where the burst length is less than 360 bits, it is possible to avoid a situation in which a plurality of the variable nodes connected to the same check node simultaneously causes errors, and as a result, it is possible to improve the resistance to the burst error.

In addition, the LDPC code after the parity interleaving in which the (K+qx+y+1)-th code bit is interleaved at the position of the (K+Py+x+1)-th code bit matches the LDPC code of a check matrix (hereinafter, also referred to as a transformed check matrix) obtained by performing the column permutation in which the (K+qx+y+1)-th column is replaced with the (K+Py+x+1)-th column in the original check matrix H.

In addition, as illustrated in FIG. 16, a pseudo-cyclic structure occurs in units of P columns (360 columns in FIG. 16) in the parity matrix of the transformed check matrix.

Herein, the pseudo-cyclic structure denotes a structure in which a part excluding a portion has a cyclic structure.

In the transformed check matrix obtained by performing the column permutation corresponding to the parity interleaving on the check matrix of the LDPC code defined in the DVB-T.2 standard or the like, the number of elements of 1 is less than 1 (to become the element of 0) in a portion (a shift matrix to be described later) of 360 rows×360 columns of the upper right corner of the transformed check matrix, and from the point of view, the structure is not a (perfect) cyclic structure but a pseudo-cyclic structure.

The transformed check matrix for the check matrix of the LDPC code output from the LDPC encoder 115 has a pseudo-cyclic structure, similarly to the transformed check matrix for the check matrix of the LDPC code defined in, for example, the DVB-T.2 standard or the like.

In addition, the transformed check matrix of FIG. 16 is a matrix in which the permutation (row permutation) for allowing the transformed check matrix to be configured as a configuration matrix to be described later, in addition to the column permutation corresponding to the parity interleaving, is performed on the original check matrix H.

FIG. 17 is a flowchart illustrating processing performed by the LDPC encoder 115, the bit interleaver 116, and the mapper 117 of FIG. 8.

After waiting for the LDPC target data to be supplied from the BCH encoder 114, in step S101, the LDPC encoder 115 encodes the LDPC target data into the LDPC code and supplies the LDPC code to the bit interleaver 116, and the process proceeds to step S102.

In step S102, the bit interleaver 116 performs bit interleaving on the LDPC code from the LDPC encoder 115 and supplies a symbol obtained by the bit interleaving to the mapper 117, and the process proceeds to step S103.

That is, in step S102, in the bit interleaver 116 (FIG. 9), the parity interleaver 23 performs parity interleaving on the LDPC code from the LDPC encoder 115 and supplies the LDPC code after the parity interleaving to the group-wise interleaver 24.

The group-wise interleaver 24 performs group-wise interleaving on the LDPC code from the parity interleaver 23 and supplies the code obtained as a result thereof to the block interleaver 25.

The block interleaver 25 performs block interleaving on the LDPC code after the group-wise interleaving by the group-wise interleaver 24 and supplies m-bit symbols obtained as a result thereof to a mapper 117.

In step S103, the mapper 117 maps the symbols from the block interleaver 25 to any one of 2^(m) signal points determined by the modulation scheme of the quadrature modulation performed by the mapper 117 and performs quadrature modulation, and supplies the data obtained as a result thereof to the time interleaver 118.

As described above, by performing the parity interleaving or the group-wise interleaving, it is possible to improve the error rate in the case of transmitting a plurality of the code bits of the LDPC code as one symbol.

Herein, in FIG. 9, for the convenience of description, the parity interleaver 23, which is a block for performing parity interleaving, and the group-wise interleaver 24, which is a block for performing group-wise interleaving, are separately configured. However, the parity interleaver 23 and the group-wise interleaver 24 can be integrally configured.

That is, both of the parity interleaving and the group-wise interleaving can be performed by writing and reading of the code bits in the memory, and the address can be indicated by a matrix transforming the address (writing address) for performing the writing of the code bits (write address) to the address (read address) for performing the reading the code bits.

Therefore, if a matrix is obtained by multiplying the matrix indicating the parity interleaving and the matrix indicating group-wise interleaving, the parity interleaving is performed by converting the code bits according to the matrix, and in addition, the result of group-wise interleaving of the LDPC code after the parity interleaving can be obtained.

Furthermore, in addition to the parity interleaver 23 and the group-wise interleaver 24, the block interleaver 25 can also be integrally configured.

That is, the block interleaving performed by the block interleaver 25 can also be indicated by a matrix for converting the write address of the memory storing the LDPC code into the read address.

Therefore, if a matrix is obtained by multiplying the matrix indicating the parity interleaving, the matrix indicating the group-wise interleaving, and the matrix indicating the block interleaving, the parity interleaving, the group-wise interleaving, and the block Interleaving can be performed collectively according to the matrix.

In addition, it can be assumed that one or the amount of parity interleaving and group-wise interleaving is not performed.

<Configuration Example of LDPC Encoder 115>

FIG. 18 is a block diagram illustrating a configuration example of the LDPC encoder 115 of FIG. 8.

Note that the LDPC encoder 122 of FIG. 8 is also configured in a similar manner.

As described with reference to FIGS. 12 and 13, in the DVB-T.2 standard or the like, LDPC codes having two types of a code length N of 64800 bits and 16200 bits are defined.

Then, for the LDPC code with a code length N of 64800 bits, 11 encoding rates of 1/4, 1/3, 2/5, 1/2, 3/5, 2/3, 3/4, 4/5, 5/6, 8/9, and 9/10 are defined, and for the LDPC code with a code length N of 16200 bits, 10 encoding rates of 1/4, 1/3, 2/5, 1/2, 3/5, 2/3, 3/4, 4/5, 5/6, and 8/9 are defined (FIGS. 12 and 13).

The LDPC encoder 115 can perform encoding (error correction coding) by the LDPC code of each encoding rate with a code length N of, for example, 64800 bits or 16200 bits according to the check matrix H prepared for each code length N and for each encoding rate.

Besides, the LDPC encoder 115 can perform LDPC encoding according to a check matrix H of an LDPC code with an arbitrary encoding rate r and an arbitrary code length N.

The LDPC encoder 115 includes an encoding processing unit 601 and a storage unit 602.

The encoding processing unit 601 includes an encoding rate setting unit 611, an initial value table reading unit 612, a check matrix generation unit 613, an information bit reading unit 614, an encoding parity calculation unit 615, and a control unit 616 and performs LDPC encoding of the LDPC target data supplied to the LDPC encoder 115 and supplies the LDPC code obtained as a result thereof to the bit interleaver 116 (FIG. 8).

That is, the encoding rate setting unit 611 sets the code length N and the encoding rate r of the LDPC code and other specific information for specifying the LDPC code, for example, according to the operator's operation or the like.

The initial value table reading unit 612 reads a check matrix initial value table, described later, indicating a check matrix of the LDPC code specified by the specific information set by the encoding rate setting unit 611 from the storage unit 602.

The check matrix generation unit 613 generates a check matrix H on the basis of the check matrix initial value table read by the initial value table reading unit 612 and stores the check matrix H in the storage unit 602. For example, the check matrix generation unit 613 arranges the elements of 1 of the information matrices H_(A) corresponding to the information length K (=code length N-parity length M) according to the code length N and the encoding rate r set by the encoding rate setting unit 611 in the column direction in a cycle of 360 columns (unit size P) to generate the check matrix H and stores the check matrix H in the storage unit 602.

The information bit reading unit 614 reads (extracts) information bits for the information length K from the LDPC target data supplied to the LDPC encoder 115.

The encoding parity calculation unit 615 reads the check matrix H generated by the check matrix generation unit 613 from the storage unit 602 and calculates the parity bits for the information bits read by the information bit reading unit 614 by using the check matrix H on the basis of a predetermined formula to generate the code word (LDPC code).

The control unit 616 controls each block constituting the encoding processing unit 601.

A plurality of the check matrix initial value tables and the like corresponding to a plurality of the encoding rates and the like illustrated in FIGS. 12 and 13 for each of the code lengths N of, for example, 64800 bits and 16200 bits are stored in the storage unit 602. In addition, the storage unit 602 temporarily stores data necessary for the processing of the encoding processing unit 601.

FIG. 19 is a flowchart for describing an example of processing of the LDPC encoder 115 of FIG. 18.

In step S201, the encoding rate setting unit 611 sets the code length N and the encoding rate r, which are to be subjected to LDPC encoding, and other specific information for specifying the LDPC code.

In step S202, the initial value table reading unit 612 reads, from the storage unit 602, a predetermined check matrix initial value table specified by the code length N, the encoding rate r, and the like as the specific information set by the encoding rate setting unit 611.

In step S203, the check matrix generation unit 613 obtains (generates) the check matrix H of the LDPC code with a code length N and an encoding rate r set by the encoding rate setting unit 611 by using the check matrix initial value table read from the storage unit 602 by the initial value table reading unit 612 and supplies and stores the check matrix H in the storage unit 602.

In step S204, the information bit reading unit 614 reads, from the LDPC target data supplied to the LDPC encoder 115, the information bits with the information length K (=N×r) corresponding to the code length N and the encoding rate r set by the encoding rate setting unit 611 and reads the check matrix H obtained by the check matrix generation unit 613 from the storage unit 602 and supplies the information bits and the check matrix H to the encoding parity calculation unit 615.

In step S205, the encoding parity calculation unit 615 sequentially calculates the parity bits of the code word c that satisfies Formula (8) by using the information bits and the check matrix H from the information bit reading unit 614. Hc ^(T)=0  (8)

In Formula (8), c indicates a row vector as a code word (LDPC code), and c^(T) indicates transposition of the row vector c.

Herein, as described above, in a case where a portion of the information bits of the row vector c as the LDPC code (one code word) is indicated by the row vector A and a portion of the parity bit is indicated by the row vector T, the row vector c can be indicated by the formula c=[A|T] by the row vector A as the information bits and the row vector T as the parity bits.

The check matrix H and the row vector c=[A|T] as the LDPC code need to satisfy the formula Hc^(T)=0, and in a case where the parity matrix H_(T) of the check matrix H=[H_(A)|H_(T)] has the staircase structure illustrated in FIG. 11, a row vector T as the parity bits constituting the row vector c=[A|T] satisfying the formula Hc^(T)=0 can be obtained sequentially by setting elements of each row to 0 in order from the element of the first row of the column vector Hc^(T) in the formula Hc^(T)=0.

The encoding parity calculation unit 615 obtains the parity bits T for the information bits A from the information bit reading unit 614 and outputs the code word c=[A|T] indicated by the information bits A and the parity bits T as an LDPC encoding result of information bits A.

After that, in step S206, the control unit 616 determines whether or not the LDPC encoding is ended. In a case where it is determined in step S206 that the LDPC encoding is not ended, that is, for example, in a case where there is still an LDPC target data to be subjected to the LDPC encoding, the process returns to step S201 (or step S204), and the processes of S201 (or step S204) to S206 are repeated.

In addition, in a case where it is determined in step S206 that the LDPC encoding is ended, that is, for example, in a case where there is no LDPC target data to be subjected to the LDPC encoding, the LDPC encoder 115 ends the process.

For the LDPC encoder 115, the check matrix initial value table (representing the check matrix) of LDPC codes with various code lengths N and encoding rates r can be prepared in advance. The LDPC encoder 115 can perform the LDPC encoding on the LDPC codes with various code lengths N and encoding rates r by using the check matrix H generated from the check matrix initial value table prepared in advance.

<Example of Check Matrix Initial Value Table>

The check matrix initial value table is a table representing positions of elements of 1's of, for example, the information matrix H_(A) (FIG. 10) corresponding to the information length K according to the code length N and the encoding rate r of the LDPC code (LDPC code defined by the check matrix H) every 360 columns (unit size P) and is generated in advance every check matrix H with each code length N and each encoding rate r.

That is, the check matrix initial value table indicates at least the positions of the elements of 1 of the information matrix H_(A) every 360 columns (unit size P).

In addition, as the check matrix H, there are a check matrix in which the entire portions of the parity matrix H_(T) have a staircase structure and a check matrix in which a portion of the parity matrix H_(T) has a staircase structure and the remaining portions becomes a diagonal matrix (unit matrix).

Hereinafter, a representation scheme of a check matrix initial value table indicating a check matrix in which a portion of the parity matrix H_(T) has a staircase structure and the remaining portion is a diagonal matrix is also referred to as a type-A scheme. In addition, a representation scheme of a check matrix initial value table indicating a check matrix in which the entire parity matrix H_(T) have a staircase structure is also referred to as a type-B scheme.

In addition, an LDPC code for a check matrix represented by a check matrix initial value table of the type-A scheme is also referred to as a type-A code, and an LDPC code for a check matrix represented by a check matrix initial value table of the type-B scheme is also referred to as a type-B code.

The notations “type A” and “type B” are notations in accordance with the ATSC 3.0 standard. For example, in the ATSC 3.0, both of the type-A code and the type-B code are adopted.

In addition, in the DVB-T.2 and the like, the type-B code is adopted.

FIG. 20 is a diagram illustrating an example of the check matrix initial value table of the type-B scheme.

That is, FIG. 20 illustrates a check matrix initial value table (representing the check matrix H) of type-B code with a code length N of 16200 bits and an encoding rate (encoding rate on the notation of the DVB-T.2) r of 1/4 defined in the DVB-T.2 standard.

The check matrix generation unit 613 (FIG. 18) obtains the check matrix H as follows by using the check matrix initial value table of the type-B scheme.

FIG. 21 is a diagram illustrating a method of obtaining the check matrix H from the check matrix initial value table of the type-B scheme.

That is, FIG. 21 illustrates the check matrix initial value table of the type-B code with a code length N of 16200 bits and an encoding rate r of 2/3 is defined in the DVB-T.2 standard.

The check matrix initial value table of the type-B scheme is a table indicating the positions of the elements of 1 of the entire information matrix H_(A) corresponding to the information length K according to the code length N and the encoding rate r of the LDPC code every 360 columns (unit size P), and in the i-th row, the row number (row number when the row number of the first row of the check matrix H is set to 0) of the elements of 1's in the (1+360×(i−1))-th column of the check matrix H is arranged by the number of column weights of the (1+360×(i−1))-th column.

Herein, since the parity matrix HT (FIG. 10) corresponding to the parity length M of the check matrix H of the type-B scheme is determined to have a staircase structure as illustrated in FIGS. 15A and 15B, if the information matrix HA (FIG. 10) corresponding to the information length K can be obtained by the check matrix initial value table, the check matrix H can be obtained.

The number of rows (k+1) of the check matrix initial value table of the type-B scheme differs depending on the information length K.

A relationship of Formula (9) is satisfied between the information length K and the number of rows (k+1) of the check matrix initial value table. K=(k+1)×360  (9)

Herein, 360 in Formula (9) is the unit size P described with reference to FIG. 16.

In the check matrix initial value table of FIG. 21, 13 numerical values are arranged in the rows of from the first row to the third row, and 3 numerical values are arranged in the rows of from the fourth row to the (k+1)-th row (the 30th row in FIG. 21).

Therefore, the column weights of the check matrix H obtained from the check matrix initial value table of FIG. 21 are 13 for the columns of from the first column to the (1+360×(3-1)-1)-th column and 3 for the columns of from the (1+360×(3-1))-th column to the K-th column.

The first row of the check matrix initial value table of FIG. 21 is 0, 2084, 1613, 1548, 1286, 1460, 3196, 4297, 2481, 3369, 3451, 4620, 2622, which indicates that, in the first column of the check matrix H, the elements of the rows of which the row numbers are 0, 2084, 1613, 1548, 1286, 1460, 3196, 4297, 2481, 3369, 3451, 4620, and 2622 are 1 (and the other elements are 0).

In addition, the second row of the check matrix initial value table of FIG. 21 is 1, 122, 1516, 3448, 2880, 1407, 1847, 3799, 3529, 373, 971, 4358, 3108, which indicates that, in the 361 (=1+360×(2-1))-th column of the check matrix H, the elements of the rows of which the row numbers are 1, 122, 1516, 3448, 2880, 1407, 1847, 3799, 3529, 373, 971, 4358, 3108 are 1.

As described above, the check matrix initial value table indicates the positions of the elements of 1 of the information matrix H_(A) of the check matrix H every 360 columns.

The columns other than the (1+360×(i−1))-th column of the check matrix H, that is, each column from the (2+360×(i−1))-th column to the (360×i)-th column are arranged by cyclically shifting the elements of 1's of the (1+360×(i−1))-th column determined by the check matrix initial value table in the downward direction (downward direction of the column) according to the parity length M.

That is, for example, the (2+360×(i−1))-th column is obtained by cyclically shifting the (1+360×(i−1))-th column by M/360 (=q) in the downward direction, and the next (3+360×(i−1))-th column is obtained by cyclically shifting the (1+360×(i−1))-th column by 2×M/360 (=2×q) in the downward direction (by cyclically shifting the (2+360×(i−1))-th column by M/360 (=q) in the downward direction).

Now, if the numerical value of the j-th column (j-th from the left) in the i-th row (i-th from the top) of the check matrix initial value table is denoted as h_(i,j) and the row number of the element of 1 of the j-th in the w-th column of the check matrix H is denoted by H_(w-j), the row number H_(w-j) of the element of 1 in the w-th column other than the (1+360×(i−1))-th column of the check matrix H can be obtained by Formula (10). H _(w-j)=mod{h _(i,j)+mod((w−1),P)xq,M)  (10)

Herein, mod(x,y) denotes the remainder of dividing x by y.

In addition, P is the unit size described above, and in the present embodiment, for example, P is 360, similarly to the DVB-T.2 standard or the like and the ATSC 3.0 standard. Furthermore, q is a value M/360 obtained by dividing the parity length M by the unit size P (=360).

The check matrix generation unit 613 (FIG. 18) specifies the row number of the element of 1 in the (1+360×(i−1))-th column of the check matrix H by using the check matrix initial value table.

In addition, the check matrix generation unit 613 (FIG. 18) obtains the row number Hw-j of the element of 1 in the w-th column other than the (1+360×(i−1))-th column of the check matrix H according to Formula (10) and generates a check matrix H in which the element of the row number obtained as described above is 1.

FIG. 22 illustrates the structure of a check matrix H of the type-A scheme.

The check matrix of the type-A scheme includes an A matrix, a B matrix, a C matrix, a D matrix, and a Z matrix.

The A matrix is a matrix to the upper left of the check matrix H of M1 rows and K columns indicated by a predetermined value M1 and information length K=code length N x encoding rate r of LDPC code.

The B matrix is a matrix having a staircase structure adjacent to the right of the A matrix of M1 rows and M1 columns.

The C matrix is an adjacent matrix below the A matrix and the B matrix of (N−K−M1) rows and (K+M1) columns.

The D matrix is a unit matrix adjacent to the right of the C matrix of (N−K−M1) rows and (N−K−M1) columns.

The Z matrix is a zero matrix (0 matrix) adjacent to the right of the B matrix of M1 rows and (N−K−M1) columns.

In the check matrix H of the type-A scheme configured by the A matrix to the D matrix and the Z matrix in this manner, a portion of the A matrix and the C matrix constitute an information matrix, and the B matrix, the remaining portion of the C matrix, the D matrix, and the Z matrix constitute the parity matrix.

In addition, since the B matrix is a matrix having a staircase structure and the D matrix is a unit matrix, a portion (a portion of the B matrix) of the parity matrix of the check matrix H of the type-A scheme has a staircase structure, and the remaining portion (portion of the D matrix) is a diagonal matrix (unit matrix).

The A matrix and C matrix have a cyclic structure every columns of the unit size P (for example, 360 columns), similarly to the information matrix of the check matrix H of the type-B scheme, and the check matrix initial value table of the type-A scheme indicates the positions of the elements of 1 of the A matrix and the C matrix every 360 columns.

Herein, as described above, since the A matrix and a portion of the C matrix constitute the information matrix, it can be said that the check matrix initial table of the type-A scheme indicating the positions of the elements of 1 of the A matrix and C matrix every 360 columns indicates at least the positions of the elements of 1 of the information matrix every 360 columns.

In addition, since the check matrix initial value table of the type-A scheme indicates the positions of the elements of 1 of the A matrix and the C matrix every 360 columns, it can also be said that the positions of the elements of 1 of a portion (remaining portion of the C matrix) of the check matrix are indicated every 360 columns.

FIG. 23 is a diagram illustrating an example of the check matrix initial value table of the type-A scheme.

That is, FIG. 23 illustrates an example of the check matrix initial value table indicating the check matrix H with a code length N of 35 bits and an encoding rate r of 2/7.

The check matrix initial value table of the type-A scheme is a table indicating the positions of the elements of 1 of the A matrix and the C matrix every unit size P, and in the i-th row, the row number (row number when the row number of the first row of the check matrix H is set to 0) of element of 1 in the (1+P×(i−1))-th column of the check matrix H is arranged by the number of column weights of the (1+P×(i−1))-th column.

Note that, herein, for simplifying the description, the unit size P is assumed to be, for example 5.

With respect to the check matrix H of the type-A scheme, there are M1, M2, Q1, and Q2 as parameters.

M1 (FIG. 22) is a parameter for determining the size of the B matrix and takes a value which is a multiple of the unit size P. By adjusting M1, the performance of the LDPC code is changed to be adjusted to a predetermined value at the time of determining the check matrix H. Herein, it is assumed that 15 which is three times the unit size P=5 is adopted as M1.

M2 (FIG. 22) takes a value M-M1 obtained by subtracting M1 from the parity length M.

Herein, since the information length K is N×r=35×2/7=10 and the parity length M is NK=35−10=25, M2 becomes M−M1=25−15=10.

Q1 is obtained according to the formula Q1=M1/P and indicates the number of shifts (the number of rows) of cyclic shifts in the A matrix.

That is, the columns other than the (1+P×(i−1))-th column of the A matrix of the check matrix H of the type-A scheme, that is, the columns from the (2+P×(i−1))-th column to the P×i-th column are arranged by cyclically shifting the element of 1 of the (1+P×(i−1))-th column determined by the check matrix initial value table in the downward direction (downward direction of the column), and Q1 indicates the number of shifts of the cyclically shifting in the A matrix.

Q2 is obtained according to the formula Q2=M2/P and indicates the number of shifts (the number of rows) of the cyclically shifting in the C matrix.

That is, columns other than the (1+P×(i−1))-th column of the C matrix of the check matrix H of the type-A scheme, that is, the columns from the (2+P×(i−1))-th column to the P×i-th column are cyclically shifted the element of 1 of the (1+P×(i−1))-th column determined by the check matrix initial value table in the downward direction (downward direction of the column), and Q2 indicates the number of shifts of the cyclically shifting in the C matrix.

Herein, in the Q1, M1/P=15/5=3, and in the Q2, M2/P=10/5=2.

In the check matrix initial value table of FIG. 23, three numerical values are arranged in the first and second rows, and one numerical value is arranged in the third to fifth rows. According to such arrangement of the numerical values, the column weights of the A matrix and the C matrix of the check matrix H obtained from the check matrix initial value table of FIG. 23 are 3 from the 1 (=1+5×(1-1))-th column to the 10 (=5×2)-th column and are 1 from the 11 (=1+5×(3-1))-th column to the 25 (=5×5)-th column.

That is, the first row of the check matrix initial value table of FIG. 23 is 2, 6, and, 18, which indicate that the elements of the rows with row numbers 2, 6, and 18 in the first column of the check matrix H are 1 (and that the other elements are 0).

Herein, in this case, since the A matrix (FIG. 22) is a matrix of 15 rows and 10 columns (M1 rows and K columns), and the C matrix (FIG. 22) is a matrix of 10 rows and 25 columns ((NK−M1) rows and (K+M1) columns), the rows with row numbers 0 to 14 of the check matrix H are rows of the A matrix, and the rows with row numbers 15 to 24 of the check matrix Hare rows of the C matrix.

Therefore, the rows #2 and #6 among the rows with row numbers 2, 6, and 18 (hereinafter, described as rows #2, #6 and #18) are rows of the A matrix, and the rows #18 is a row of the C matrix.

The second row of the check matrix initial value table of FIG. 23 is 2, 10, and 19, which indicate that the elements of #2, #10, and #19 are 1 in the 6 (=1+5×(2-1))-th column of the check matrix H.

Herein, in the 6 (=1+5×(2−1))-th column of the check matrix H, the rows #2 and #10 among the rows #2, #10, and #19 are rows of A matrix, and the row #19 is a row of the C matrix.

The third row of the check matrix initial value table of FIG. 23 is 22, which indicates that the element of the row #22 is 1 in the (=1+5×(3−1))-th column of the check matrix H.

Herein, in the 11 (=1+5×(3-1))-th column of the check matrix H, the row #22 is a row of the C matrix.

Similarly, 19 of the fourth row of the check matrix initial value table of FIG. 23 indicates that the element of the row #19 is 1 in the 16 (=1+5×(4-1))-th column of the check matrix H, and 15 of the fifth row of the check matrix initial value table of FIG. 23 indicates that the element of the row #15 is 1 in the 21 (=1+5×(5−1))-th column of the check matrix H.

As described above, the check matrix initial value table indicates the positions of the elements of 1 of the A matrix and the C matrix of the check matrix H every unit size P=5 columns.

The columns other than the (1+5×(i−1))-th columns of the A matrix nd the C matrix of the check matrix H, that is, each column from the (2+5×(i−1))-th column to the (5×i)-th column are arranged by cyclically shifting the element of 1 of the (1+5×(i−1))-th column determined by the check matrix initial value table in the downward direction (downward direction of the column) according to the parameters Q1 and Q2.

That is, for example, the (2+5×(i−1))-th column of the A matrix is obtained by cyclically shifting the (1+5×(i−1))-th column by Q1 (=3) in the downward direction, and the next (3+5×(i−1))-th column is obtained by cyclically shifting the (1+5×(i−1))-th column by 2×Q1 (=2×3) in the downward direction (by cyclically shifting the ((2+5×(i−1))-th column by Q1 in the downward direction).

In addition, for example, the (2+5×(i−1))-th column of the C matrix is obtained by cyclically shifting the (1+5×(i−1))-th column by Q2 (=2) in the downward direction, and the next (3+5×(i−1))-th column is obtained by cyclically shifting the (1+5×(i−1))-th column by 2×Q2 (=2×2) in the downward direction (by cyclically shifting the (2+5×(i−1))-th column by Q2 in the downward direction).

FIG. 24 is a diagram illustrating an A matrix generated from the check matrix initial value table of FIG. 23.

In the A matrix of FIG. 24, according to the first row of the check matrix initial value table of FIG. 23, the elements of the rows #2 and #6 in the 1 (=1+5×(1-1))-th column become 1.

Then, each row from the 2 (=2+5×(1-1))-th row to the 5 (=5+5×(1-1))-th row is obtained by cyclically shifting the previous row by Q1=3 in the downward direction.

Furthermore, in the A matrix of FIG. 24, according to the second row of the check matrix initial value table of FIG. 23, the elements of the rows #2 and #10 in the 6 (=1+5×(2-1))-th column become 1.

Then, each column from the 7 (=2+5×(2-1))-th column to the 10 (=5+5×(2-1))-th column is obtained by cyclically shifting the previous column by Q1=3 in the downward direction.

FIG. 25 is a diagram illustrating the parity interleaving of the B matrix.

The check matrix generation unit 613 (FIG. 18) generates an A matrix by using the check matrix initial value table, and arranges a B matrix having a staircase structure next to the A matrix. Then, the check matrix generation unit 613 regards the B matrix as a parity matrix, and performs the parity interleaving so that adjacent elements of 1 of the B matrix having a staircase structure are separated by the unit size P=5 in the row direction.

FIG. 25 illustrates the A matrix and the B matrix after the parity interleaving of the B matrix of FIG. 24.

FIG. 26 is a diagram illustrating the C matrix generated from the check matrix initial value table of FIG. 23.

In the C matrix of FIG. 26, according to the first row of the check matrix initial value table of FIG. 23, the element of the row #18 of the 1 (=1+5×(1-1))-th column of the check matrix H becomes 1.

Then, each column from the 2 (=2+5×(1-1))-th column to the 5 (=5+5×(1-1))-th column of the C matrix is obtained by cyclically shifting the previous column by Q2=2 in the downward direction.

Furthermore, in the C matrix of FIG. 26, according to the second to fifth rows of the check matrix initial value table of FIG. 23, the elements of the row #19 in the 6 (=1+5×(2-1))-th column of the check matrix H, the row #22 in the 11 (=1+5×(3-1))-th column, the row #19 in the 16 (=1+5×(4-1))-th column, and the row #15 in the 21 (=1+5×(5-1))-th column become 1.

Then, each column from the 7 (=2+5×(2-1))-th column to the 10 (=5+5×(2-1))-th column, each column from the 12 (=2+5×(3-1))-th column to the 15 (=5+5×(3-1))-th column, each column from the 17 (=2+5×(4-1))-th column to 20 (=5+5×(4-1)-th column, and each row from the 22 (=2+5×(5-1))-th column to the 25 (=5+5×(5-1))-th column are obtained by cyclically shifting the previous column by Q2=2 in the downward direction.

The check matrix generation unit 613 (FIG. 18) generates the C matrix using the check matrix initial value table and arranges the C matrix below the A matrix and the B matrix (after the parity interleaving).

In addition, the check matrix generation unit 613 arranges the Z matrix next to the right of the B matrix and arranges the D matrix next to the right of the C matrix to generate the check matrix H illustrated in FIG. 26.

FIG. 27 is a diagram illustrating the parity interleaving of the D matrix.

After the check matrix generation unit 613 generates the check matrix H of FIG. 26, the D matrix is regarded as a parity matrix, and the parity interleaving (only of the D matrix) is performed so that the elements of 1 of the odd rows and the next even rows of the D matrix of the unit matrix are separated by a unit size P=5 in the row direction.

FIG. 27 illustrates the check matrix H after the parity interleaving of the D matrix is performed on the check matrix H of FIG. 26.

The LDPC encoder 115 (encoding parity calculation unit 615 (FIG. 18)) performs, for example, the LDPC encoding (generation of the LDPC code) by using the check matrix H of FIG. 27.

Herein, the LDPC code generated by using the check matrix H of FIG. 27 becomes an LDPC code subjected to the parity interleaving, and thus, for the LDPC code generated by using the check matrix H of FIG. 27, it is not necessary to perform the parity interleaving in the parity interleaver 23 (FIG. 9). That is, since the LDPC code generated by using the check matrix H after performing the parity interleaving of the D matrix becomes an LDPC code subjected to the parity interleaving, the parity interleaving in the parity interleaver 23 for such an LDPC code is skipped.

FIG. 28 illustrates is a diagram illustrating the check matrix H obtained by performing the column permutation as the parity deinterleaving for returning the parity interleaving to the original parity interleaving on the B matrix, a portion of the C matrix (a portion of the C matrix located below the B matrix), and the D matrix of the check matrix H of FIG. 27.

The LDPC encoder 115 can perform the LDPC encoding (generation of the LDPC code) by using the check matrix H of FIG. 28.

In a case where the LDPC encoding is performed by using the check matrix H of FIG. 28, according to the LDPC encoding, an LDPC code which has not been subjected to the parity interleaving can be obtained. Therefore, in a case where the LDPC encoding is performed by using the check matrix H of FIG. 28, the parity interleaving is performed in the parity interleaver 23 (FIG. 9).

FIG. 29 is a diagram illustrating a transformed check matrix H obtained by performing row permutation on the check matrix H of FIG. 27.

As described later, the transformed check matrix is a matrix represented by a combination of P×P unit matrices, quasi-unit matrices in which one or more of 1's of the unit matrix become 0, shift matrices obtained by cyclically shifting the unit matrix or the quasi-unit matrix, sum matrices, each of which is a sum of two or more of the unit matrices, the quasi-unit matrices, or the shift matrices, and P×P zero matrices.

By using the transformed check matrix for the decoding of the LDPC code, it is possible to adopt an architecture for simultaneously performing P check node operations and variable node operations in the decoding of the LDPC code, as described later.

<New LDPC Code>

In data transmission using an LDPC code, as one of methods to ensure a good communication quality, there is a method of using an LDPC code with high-performance.

In the following, a new high performance LDPC code (hereinafter, also referred to as a new LDPC code) will be described.

As the new LDPC code, for example, a type-A code or a type-B code corresponding to the check matrix H having a cyclic structure may be adopted with a unit size P of 360 similar to that of DVB-T.2, ATSC 3.0, or the like.

The LDPC encoder 115 (FIGS. 8 and 18) can perform the LDPC encoding on a new LDPC code by using the check matrix initial value table (the check matrix H obtained from the new LDPC code) of the new LDPC with a code length N of being longer than 64 k bits, for example, 69120 bits and an encoding rate r of any one of for example, 2/16, 3/16, 4/16, 5/16, 6/16, 7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, or 14/16, as follows.

In this case, the check matrix initial value table of the new LDPC code is stored in the storage unit 602 of the LDPC encoder 115 (FIG. 8).

FIG. 30 is a diagram illustrating an example of the check matrix initial value table (of type-A scheme) indicating a check matrix H of a type-A code (hereinafter, also referred to as a type-A code with r=2/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 2/16.

FIGS. 31 and 32 are diagrams illustrating an example of the check matrix initial value table indicating a check matrix H of a type-A code (hereinafter, also referred to as a type-A code with r=3/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 3/16.

Note that FIG. 32 is a diagram following FIG. 31.

FIG. 33 is a diagram illustrating an example of the check matrix initial value table (of type-A scheme) indicating a check matrix H of a type-A code (hereinafter, also referred to as a type-A code with r=4/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 4/16.

FIGS. 34 and 35 are diagrams illustrating an example of the check matrix initial value table indicating a check matrix H of a type-A code (hereinafter, also referred to as a type-A code with r=5/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 5/16.

Note that FIG. 35 is a diagram following FIG. 34.

FIGS. 36 and 37 are diagrams illustrating an example of the check matrix initial value table indicating a check matrix H of a type-A code (hereinafter, also referred to as a type-A code with r=6/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 6/16.

Note that FIG. 37 is a diagram following FIG. 36.

FIGS. 38 and 39 are diagrams illustrating an example of the check matrix initial value table indicating a check matrix H of a type-A code (hereinafter, also referred to as a type-A code with r=7/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 7/16.

Note that FIG. 39 is a diagram following FIG. 38.

FIGS. 40 and 41 are diagrams illustrating an example of the check matrix initial value table indicating a check matrix H of a type-A code (hereinafter, also referred to as a type-A code with r=8/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 8/16.

Note that FIG. 41 is a diagram following FIG. 40.

FIGS. 42 and 43 are diagrams illustrating an example of the check matrix initial value table indicating a check matrix H of a type-B code (hereinafter, also referred to as a type-B code with r=7/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 7/16.

Note that FIG. 43 is a diagram following FIG. 42.

FIGS. 44 and 45 are diagrams illustrating another example of the check matrix initial value table indicating a check matrix H of the type-B code with r=7/16.

Note that FIG. 45 is a diagram following FIG. 44. The type-B code with r=7/16 obtained from (the check matrix H indicated by) the check matrix initial value table of FIGS. 44 and 45 is hereinafter also referred to as another type-B code with r=7/16.

FIGS. 46 and 47 are diagrams illustrating an example of the check matrix initial value table indicating a check matrix H of a type-B code (hereinafter, also referred to as a type-B code with r=8/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 8/16.

Note that FIG. 47 is a diagram following FIG. 46.

FIGS. 48 and 49 are diagrams illustrating another example of a check matrix initial value table indicating a check matrix H of a type-B code with r=8/16.

Note that FIG. 49 is a diagram following FIG. 48. Hereinafter, the type-B code with r=8/16 obtained from the check matrix initial value table of FIGS. 48 and 49 is also referred to as another type-B code with r=8/16.

FIGS. 50, 51, and 52 are diagrams illustrating an example of a check matrix initial value table indicating a check matrix H of a type-B code (hereinafter, also referred to as type-B code with r=9/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 9/16.

Note that FIG. 51 is a diagram following FIG. 50, and FIG. 52 is a diagram following FIG. 51.

FIGS. 53, 54 and 55 are diagrams illustrating other examples of the check matrix initial value tables indicating check matrix H of type-B code with r=9/16.

Note that FIG. 54 is a diagram following FIG. 53, and FIG. 55 is a diagram following FIG. 54. Hereinafter, the type-B code with r=9/16 obtained from the check matrix initial value table of FIGS. 53 to 55 is also referred to as another type-B code with r=9/16.

FIGS. 56, 57, and 58 are diagrams illustrating an example of a check matrix initial value table indicating a check matrix H of a type-B code (hereinafter, also referred to as a type-B code with r=10/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 10/16.

Note that FIG. 57 is a diagram following FIG. 56, and FIG. 58 is a diagram following FIG. 57.

FIGS. 59, 60, and 61 are diagrams illustrating another example of a check matrix initial value table indicating a check matrix H of a type-B code with r=10/16.

Note that FIG. 60 is a diagram following FIG. 59, and FIG. 61 is a diagram following FIG. 60. Hereinafter, the type-B code with r=10/16 obtained from the check matrix initial value table of FIGS. 59 to 61 is also referred to as another type-B code with r=10/16.

FIGS. 62, 63, and 64 are diagrams illustrating an example of a check matrix initial value table indicating a check matrix H of a type-B code (hereinafter, also referred to as a type-B code with r=11/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 11/16.

Note that FIG. 63 is a diagram following FIG. 62, and FIG. 64 is a diagram following FIG. 63.

FIGS. 65, 66 and 67 are diagrams illustrating other examples of a check matrix initial value table indicating a check matrix H of a type-B code with r=11/16.

Note that FIG. 66 is a diagram following FIG. 65, and FIG. 67 is a diagram following FIG. 66. Hereinafter, the type-B code with r=11/16 obtained from the check matrix initial value table of FIGS. 65 to 67 is also referred to as another type-B code with r=11/16.

FIGS. 68, 69, and 70 are diagrams illustrating an example of a check matrix initial value table indicating a check matrix H of a type-B code (hereinafter, also referred to as a type-B code with r=12/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 12/16.

Note that FIG. 69 is a diagram following FIG. 68, and FIG. 70 is a diagram following FIG. 69.

FIGS. 71, 72, and 73 are diagrams illustrating another example of a check matrix initial value table indicating a check matrix H of a type-B code with r=12/16.

Note that FIG. 72 is a diagram following FIG. 71, and FIG. 73 is a diagram following FIG. 72. Hereinafter, the type-B code with r=12/16 obtained from the check matrix initial value table of FIGS. 71 to 73 is also referred to as another type-B code with r=12/16.

FIGS. 74, 75, and 76 are diagrams illustrating an example of a check matrix initial value table indicating a check matrix H of a type-B code (hereinafter, also referred to as a type-B code with r=13/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 13/16.

Note that FIG. 75 is a diagram following FIG. 74, and FIG. 76 is a diagram following FIG. 75.

FIGS. 77, 78, and 79 are diagrams illustrating another example of a check matrix initial value table indicating a check matrix H of a type-B code with r=13/16.

Note that FIG. 78 is a diagram following FIG. 77, and FIG. 79 is a diagram following FIG. 78. Hereinafter, the type-B code with r=13/16 obtained from the check matrix initial value table of FIGS. 77 to 79 is also referred to as another type-B code with r=13/16.

FIGS. 80, 81, and 82 are diagrams illustrating an example of a check matrix initial value table indicating a check matrix H of a type-B code (hereinafter, also referred to as a type-B code with r=14/16) as a new LDPC code with a code length N of 69120 bits and an encoding rate r of 14/16.

Note that FIG. 81 is a diagram following FIG. 80, and FIG. 82 is a diagram following FIG. 81.

FIGS. 83, 84 and 85 are diagrams illustrating other examples of a check matrix initial value table indicating check matrix H of a type-B code with r=14/16.

Note that FIG. 84 is a diagram following FIG. 83, and FIG. 85 is a diagram following FIG. 84. Hereinafter, the type-B code with r=14/6 obtained from the check matrix initial value table of FIGS. 83 to 85 is also referred to as another type-B code with r=14/16.

The new LDPC code has become a high-performance LDPC code.

Herein, the high-performance LDPC code is an LDPC code obtained from an appropriate check matrix H.

An appropriate check matrix H is a check matrix that satisfies a predetermined condition which allows a bit error rate (BER) (and frame error rate (FER)) to be smaller, for example, when the LDPC code obtained from the check matrix H is transmitted at a low E_(s)/N₀ or E_(b)/N_(o) (signal power to noise power ratio per bit).

The appropriate check matrix H can be obtained, for example, by performing simulation to measure the BER when the LDPC code obtained from various check matrices satisfying the predetermined condition is transmitted at a low E_(s)/N_(o).

As the predetermined condition to be satisfied by the appropriate check matrix H, there is, for example, a condition that the analysis result obtained by an analysis method for the performance of a code called density evolution is good, a condition that a loop of elements of 1 called ‘Cycle 4’ does not exist, or the like.

Herein, it is known that the decoding performance of the LDPC code is deteriorated if the elements of 1 are densely packed in the information matrix H_(A) as in the Cycle 4, and thus, it is desirable that the Cycle 4 does not exist in the check matrix H.

In the check matrix H, the minimum value of the length (loop length) of a loop formed by elements of 1 is referred to as a girth. The absence of the Cycle 4 denotes that the girth is greater than four.

In addition, the predetermined condition to be satisfied by the appropriate check matrix H can be appropriately determined from the point of view of the improvement in the decoding performance of the LDPC code, the facilitation (simplification) of the decoding processing of the LDPC code, and the like.

FIGS. 86 and 87 are diagrams for describing density evolution in which an analysis result is obtained as a predetermined condition that an appropriate check matrix H is to satisfy.

The density evolution is a code analysis method of calculating an expectation value of an error probability for the entire LDPC code (ensemble) with a code length N of ∞ characterized by the later-described degree sequence.

For example, on an AWGN channel, if the variance value of noise is increased from 0, the expectation value of the error probability of a certain ensemble is initially 0, but if the variance value of noise is greater than or equal to a certain threshold, the expectation value of the error probability of the ensemble is not 0.

According to the density evolution, it can be determined whether or not the performance (appropriateness of the check matrix) of the ensemble is high by comparing a threshold (hereinafter, also referred to as performance threshold) of the variance value of noise, where the expectation value of the error probability is not 0.

In addition, for a specific LDPC code, if an ensemble to which the LDPC code belongs is determined and density evolution is performed on the ensemble, the performance of the LDPC code can be roughly predicted.

Therefore, if a high-performance ensemble is found, a high-performance LDPC code can be found among the LDPC codes belonging to the ensemble.

Herein, the above-described degree sequence indicates at which degree of ratio the variable nodes or check nodes having weights of respective values are present with respect to the code length N of the LDPC code.

For example, a regular (3, 6) LDPC code with an encoding rate of 1/2 belongs to the ensemble characterized by the degree sequence where the weight (column weight) of all the variable nodes is 3 and the weight (row weight) of all the check nodes is 6.

FIG. 86 illustrates a Tanner graph of such an ensemble.

In the Tanner graph of FIG. 86, there exist only N variable nodes indicated by circles (◯) in the figure, of which the number is equal to the code length N, and there exist only N/2 check nodes indicated by squares (□) in the figure, of which the number is equal to the value obtained by multiplying the code length N by the encoding rate 1/2.

Three branches (edges) equal to the column weights are connected to each variable node, and thus, there are a total of 3N branches connected to the N variable nodes.

In addition, six branches equal to the row weights are connected to each check node, and thus, there are a total of 3N branches connected to the N/2 check nodes.

Furthermore, in the Tanner graph of FIG. 86, there is one interleaver.

The interleaver randomly rearranges the 3N branches connected to the N variable nodes, and each branch after the rearrangement is connected to any one of the 3N branches connected to the N/2 check nodes.

In the interleaver, there are only (3N)! (=(3N)×(3N−1)× . . . ×1) rearrangement patterns for rearranging the 3N branches connected to the N variable nodes. Therefore, an ensemble characterized by the degree sequence that the weight of all the variable nodes is 3 and the weight of all the check nodes is 6 is a set of (3N)! LDPC codes.

In the simulation for obtaining a high-performance LDPC code (appropriate check matrix), an ensemble of a multi-edge type was used in the density evolution.

In the multi-edge type, an interleaver, through which branches connected to the variable node and branches connected to the check node pass, are divided into a plurality of (multi edge) ones, so that the characterization of the ensemble is more strictly performed.

FIG. 87 illustrates an example of a Tanner graph of a multi-edge type ensemble.

In the Tanner graph of FIG. 87, there are two interleavers of a first interleaver and a second interleaver.

In addition, in the Tanner graph in FIG. 87, there exist only v1 variable nodes, each of which has one branch connected to the first interleaver and no branch connected to the second interleaver, there exist only v2 variable nodes, each of which has one branch connected to the first interleaver and two branches connected to the second interleaver, and there exist only v3 variable nodes, each of which has no branch connected to the first interleaver and two branches connected to the second interleaver.

Furthermore, in the Tanner graph in FIG. 87, there exist only c1 variable nodes, each of which has two branches connected to the first interleaver and no branch connected to the second interleaver, there exist only c2 variable nodes, each of which has two branches connected to the first interleaver and two branches connected to the second interleaver, and there exist only c3 variable nodes, each of which has no branch connected to the first interleaver and three branches connected to the second interleaver.

Herein, the density evolution and implementation thereof are disclosed in, for example, “On the Design of Low-Density Parity-Check Codes within 0.0045 dB of the Shannon Limit”, S. Y. Chung, G. D. Forney, T. J. Richardson, R. Urbanke, IEEE Communications Leggers, VOL. 5, NO. 2, February 2001.

In the simulation for obtaining (the check matrix of) the new LDPC code, the ensemble of which the performance threshold was E_(b)/N_(o) (signal power to noise power ratio per bit) at which the BER started to fall (becomes smaller) due to the multi-edge type density evolution became a predetermined value or less was found, the LDPC code reducing the BER of the case of using one or more quadrature modulations such as QPSK among the LDPC codes belonging to the ensemble was selected as a good LDPC code.

The new LDPC code (a check matrix initial value table indicating a check matrix thereof) was obtained by the above simulation.

Therefore, according to the new LDPC code, good communication quality can be ensured in the data transmission.

FIG. 88 is a diagram illustrating column weights of a check matrix H of a type-A code as a new LDPC code.

With respect to the check matrix H of the type-A code, as illustrated in FIG. 88, the column weight of the K1 columns from the first column of the A matrix is indicated as Y1, the column weight of the subsequent K2 columns of the A matrix is indicated as Y2, the column weight of the K1 columns from the first column of the C matrix is indicated as X1, the column weight of the subsequent K2 columns of the C matrix is indicated as X2, and the column weight of the further subsequent M1 columns of the C matrix is indicated as X3.

In addition, K1+K2 is equal to the information length K, and M1+M2 is equal to the parity length M. Therefore, K1+K2+M1+M2 is equal to the code length N=69120 bits.

In addition, with respect to the check matrix H of the type-A code, the column weight of the M1-1 columns from the first column of the B matrix is indicated as 2, and the column weight of the M1-th column (last column) of the B matrix is indicated as 1. Furthermore, the column weight of the D matrix is 1, and the column weight of the Z matrix is 0.

FIG. 89 is a diagram illustrating parameters of the check matrix H of the type-A code (represented by the check matrix initial value table) in FIGS. 30 to 41.

X1, Y1, K1, X2, Y2, K2, X3, M1, and M2 as parameters of the check matrix H of the type-A codes of r=2/16, 3/16, 4/16, 5/16, 6/16, 7/16, and 8/16 and the performance threshold are as illustrated in FIG. 89.

The parameters X1, Y1, K1 (or K2), X2, Y2, ×3, and M1 (or M2) are set so as to further improve the performance (for example, the error rate or the like) of the LDPC code.

FIG. 90 is a diagram illustrating column weights of a check matrix H of a type-B code as a new LDPC code.

With respect to the check matrix H of the type-B code, as illustrated in FIG. 90, the column weight of the KX1 columns from the first column is indicated as X1, the column weight of the subsequent KX2 columns is indicated as X2, the column weight of the subsequent KY1 columns is indicated as Y1, and the column weight of the subsequent KY2 columns is indicated as Y2.

Note that KX1+KX2+KY1+KY2 is equal to the information length K, and KX1+KX2+KY1+KY2+M is equal to the code length N=69120 bits.

In addition, for the check matrix H of the type-B code, the column weight of the M−1 columns excluding the last column among the last M columns is 2, and the column weight of the last column is 1.

FIG. 91 is a diagram illustrating parameters of the check matrix H of the type-B code (represented by the check matrix initial value table) in FIGS. 42 to 85.

X1, KX1, X2, KX2, Y1, KY1, Y2, KY2, M as parameters of the check matrix H of the type-B codes of r=7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, and 14/16 and other type-B codes and the performance threshold are as illustrated in FIG. 91.

The parameters X1, KX1, X2, KX2, Y1, KY1, Y2, and KY2 are set so as to further improve the performance of the LDPC code.

According to the new LDPC code, a good BER/FER is realized, and a capacity (transmission line capacity) close to the Shannon limit is realized.

<Constellation>

FIGS. 92, 93, 94, 95A, 95B, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113A, 113B, 114, 115, and 116 illustrate examples of constellations that can be adopted in the transmission system of FIG. 7.

In the transmission system of FIG. 7, for example, a constellation used in MODCOD can be set for the MODCOD which is a combination of a modulation scheme (MODulation) and an LDPC code (CODe).

For one MODCOD, one or more constellations can be set.

The constellation includes uniform constellation (UC) in which the arrangement of signal points is uniform and non-uniform constellation (NUC) in which the arrangement of signal points is not uniform.

In addition, the NUC includes, for example, a constellation called 1-dimensional (M2-QAM) non-uniform constellation (1D-NUC), a constellation called 2-dimensional (QQAM) non-uniform constellation (2D-NUC), and the like.

In general, the 1D-NUC improves BER over the UC, and the 2D-NUC improves BER over the 1D-NUC.

The constellation with a modulation scheme of QPSK becomes UC. For example, the UC or the 2D-NUC can be adopted as the constellation with a modulation scheme of 16QAM, 64QAM, 256QAM, or the like, and for example, the UC or the 1D-NUC can be adopted as the constellation with a modulation scheme of 1024QAM, 4096QAM, or the like.

In the transmission system of FIG. 7, for example, the constellations defined by ATSC 3.0, DVB-C.2, or the like, and various other constellations that improve the error rate can be used.

That is, in a case where the modulation scheme is QPSK, for example, the same UC can be used for each encoding rate r of the LDPC code.

In addition, in a case where the modulation scheme is 16QAM, 64QAM, or 256QAM, for example, the same UC can be used for each encoding rate r of the LDPC code. Furthermore, in a case where the modulation scheme is 16QAM, 64QAM, or 256QAM, for example, different 2D-NUCs can be used for each encoding rate r of the LDPC code.

In addition, in a case where the modulation scheme is 1024QAM or 4096QAM, for example, the same UC can be used for each encoding rate r of the LDPC code. Furthermore, in a case where the modulation scheme is 1024QAM or 4096QAM, for example, different 1D-NUC can be used for each encoding rate r of the LDPC code.

Herein, the UC of QPSK is also described as QPSK-UC, and the UC of 2^(m)QAM is also described as 2^(m)QAM-UC. In addition, the 1D-NUC of 2^(m)QAM and the 2D-NUC of 2^(m)QAM are also described as 2^(m)QAM-1D-NUC and 2^(m)QAM-2D-NUC, respectively.

Hereinafter, some of the constellations defined in ATSC 3.0 will be described.

FIG. 92 is a diagram illustrating the coordinates of signal points of QPSK-UC used for all encoding rates of an LDPC code defined in ATSC 3.0 in a case where the modulation scheme is QPSK.

In FIG. 92, “Input Data Cell y” indicates a 2-bit symbol to be mapped to QPSK-UC, and “Constellation point z_(s)” indicates the coordinates of a signal point z_(s). Note that the index s of the signal point z_(s) (as well as the index q of the signal point z_(q) described later) indicates the discrete time of the symbols (time interval between one symbol and the next symbol).

In FIG. 92, the coordinates of the signal point z_(s) are expressed in the form of a complex number, and j indicates an imaginary unit (√(−1))

FIG. 93 is a diagram illustrating the coordinates of the signal point of the 16QAM-2D-NUC used for the encoding rate r (CR)=2/15, 3/15, 4/15, 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12/15, and 13/15 of the LDPC code defined in ATSC 3.0 in a case where the modulation scheme is 16QAM.

In FIG. 93, similarly to FIG. 92, the coordinates of the signal point z_(s) are expressed in the form of a complex number, and j indicates an imaginary unit.

In FIG. 93, w #k indicates the coordinates of the signal point in the first quadrant of the constellation.

In the 2D-NUC, a signal point in the second quadrant of the constellation is placed at a position where the signal point in the first quadrant is moved symmetrically with respect to the Q-axis, and a signal point in the third quadrant of the constellation is placed at a position where the signal point in the first quadrant is moved symmetrically with respect to the origin. Then, a signal point in the fourth quadrant of the constellation is placed at a position where the signal point in the first quadrant is moved symmetrically with respect to the I-axis.

Herein, in a case where the modulation scheme is 2^(m)QAM, m bits are set as one symbol, and the one symbol is mapped to a signal point corresponding to the symbols.

An m-bit symbol can be represented, for example, by an integer value of 0 to 2^(m)−1. However, if b=2^(m)/4, the symbols y(0), y(1), . . . , and y (2^(m)−1) represented by an integer value of 0 to 2^(m)−1 can be classified into four of the symbols y (0) to y(b−1), the symbols y (b) to y(2b−1), the symbols y(2b) to y(3b−1), and the symbols y(3b) to y(4b−1).

In FIG. 93, the suffix k of w #k has an integer value in the range of 0 to b−1, and w #k indicates the coordinates of the signal point corresponding to the symbol y(k) in the range of the symbols y(0) to y(b−1).

Then, the coordinates of the signal point corresponding to the symbol y (k+b) in the range of the symbols y (b) to y (2b−1) are indicated by −conj (w #k), and the coordinates of the signal point corresponding to the symbol y(k+2b) in the range of the symbols y(2b) to y(3b−1) are indicated by conj (w #k). In addition, the coordinates of the signal point corresponding to the symbol y (k+3b) in the range of the symbols y(3b) to y(4b−1) are indicated by −w #k.

Herein, conj(w #k) indicates a complex conjugate of w #k.

For example, in a case where the modulation scheme is 16QAM, the symbols y(0), y(1), . . . , and y(15) with m=4 bits are classified into four ranges of the symbols y(0) to y(3), symbols y(4) to y(7), symbols y(8) to y(11), and symbols y(12) to y(15) with b=2⁴/4=4.

Then, since, for example, the symbol y(12) among the symbols y(0) to y(15) is the symbol y(k+3b)=y(0+3×4) in the range of the symbols y (3b) to y (4b−1)) and k=0, the coordinates of the signal point corresponding to the symbol y(12) are −w #k=−w0.

Now, assuming that the encoding rate r (CR) of the LDPC code is, for example, 9/15, according to FIG. 93, w0 of the case where the modulation scheme is 16QAM and the encoding rate r is 9/15 is 0.2386+j0.5296, the coordinate −w0 of the signal point corresponding to the symbol y(12) is −(0.2386+j0.5296).

FIG. 94 is a diagram illustrating an example of the coordinate of the signal point of the 1024QAM-1D-NUC used for the encoding rate r(CR)=2/15, 3/15, 4/15, 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12/15, and 13/15 of the LDPC code defined in ATSC 3.0 in a case where the modulation scheme is 1024QAM.

In FIG. 94, u #k indicates the real part Re (z_(s)) and the imaginary part Im(z_(s)) of a complex number as the coordinates of the signal point z_(s) of 1D-NUC and are the components of a vector u=(u0, u1, . . . , u #V−1) referred to as a position vector. The number V of components u #k of the position vector u is given by the formula V=√(2^(m))/2.

FIGS. 95A and 95B are diagrams illustrating a relationship between a symbol y of 1024QAM and (components u #k of) a position vector u.

Now, it is assumed that a 10-bit symbol y of the 1024QAM is represented by y_(0,s), y_(1,s), y_(2,s), y_(3,s), y_(4,s), y_(5,s), y_(6,s), y_(7,s), y_(8,s), and y_(9,s) from the leading bit (most significant bit) thereof.

FIG. 95A illustrates the correspondence between the even-numbered 5 bits y_(1,s), y_(3,s), y_(5,s), y_(7,s), and y_(9,s) of the symbol y and the u #k indicating the real part Re(z_(s)) of (the coordinates of) the signal point z_(s) corresponding to the symbol y.

FIG. 95B illustrates the correspondence between the odd-numbered 5 bits y_(0,s), y_(2,s), y_(4,s), y_(6,s), and y_(8,s) of the symbol y and the u #k indicating the imaginary part Im(z_(s)) of the signal point z_(s) corresponding to the symbol y.

In a case where the 10-bit symbol y=(y_(0,s), y_(1,s), y_(2,s), y_(3,s), y_(4,s), y_(5,s), y_(6,s), y_(7,s), y_(8,s), y_(9,s)) of the 1024QAM is, for example, (0, 0, 1, 0, 0, 1, 1, 1, 0, 0), the odd-numbered 5 bits (y_(0,s), y_(2,s), y_(4,s), y_(6,s), y_(8,s)) is (0, 1, 0, 1, 0), and the even-numbered 5 bits (y_(1,s), y_(3,s), y_(5,s), y_(7,s), y_(9,s)) is (0, 0, 1, 1, 0).

In FIG. 95A, the even-numbered 5 bits (0, 0, 1, 1, 0) are associated with u11, and thus, the real part Re(z_(s)) of the signal point z_(s) corresponding to the symbol y=(0, 0, 1, 0, 0, 1, 1, 1, 0, 0) becomes u11.

In FIG. 95B, the odd-numbered 5 bits (0, 1, 0, 1, 0) are associated with u3, and thus, the imaginary part Im(z_(s)) of the signal point z_(s) corresponding to the symbol y=(0, 0, 1, 0, 0, 1, 1, 1, 0, 0) becomes u3.

On the other hand, assuming that the encoding rate r of the LDPC code is, for example, 6/15, according to FIG. 94 described above, for the 1D-NUC used in a case where the modulation scheme is 1024QAM and the encoding rate r(CR) of the LDPC code is 6/15, u3 is 0.1295, and u11 is 0.7196.

Therefore, the real part Re(z_(s)) of the signal point z_(s) corresponding to the symbol y=(0, 0, 1, 0, 0, 1, 1, 1, 0, 0) becomes u11=0.7196, and the imaginary part Im(z_(s)) becomes u3=0.1295. As a result, the coordinates of the signal point z_(s) corresponding to the symbol y=(0, 0, 1, 0, 0, 1, 1, 1, 0, 0) are indicated by 0.7196+j0.1295.

In addition, the signal points of the 1D-NUC are arranged in a lattice on a straight line parallel to the I-axis or a straight line parallel to the Q-axis on the constellation. However, the interval between signal points is not constant. In addition, the average power of the signal points on the constellation can be normalized in the transmission of (the data mapped to) the signal points. Assuming that P_(ave) indicates the root mean square of absolute values of all (the coordinates of) the signal points on the constellation, the normalization can be performed by multiplying each signal point z_(s) on the constellation by the reciprocal 1/(√P_(ave)) of the square root √P_(ave) of the root mean square P_(ave).

The transmission system of FIG. 7 can use the constellation defined in ATSC 3.0 as described above.

FIGS. 96 to 107 illustrate coordinates of signal points of UC defined in DVB-C.2.

That is, FIG. 96 is a diagram illustrating a real part Re(z_(q)) of coordinates z_(q) of a signal point of QPSK-UC (UC in QPSK) defined in DVB-C.2. FIG. 97 is a diagram illustrating an imaginary part Im (z_(q)) of the coordinates z_(q) of the signal point of the QPSK-UC defined in DVB-C.2.

FIG. 98 is a diagram illustrating a real part Re (z_(q)) of coordinates z_(q) of a signal point of 16QAM-UC (UC in 16QAM) defined in DVB-C.2. FIG. 99 is a diagram illustrating an imaginary part Im(z_(q)) of the coordinates z_(q) of the signal point of the 16QAM-UC defined in DVB-C.2.

FIG. 100 is a diagram illustrating a real part Re(z_(q)) of coordinates z_(q) of a signal point of 64QAM-UC (UC in 64QAM) defined in DVB-C.2. FIG. 101 is a diagram illustrating an imaginary part Im (z_(q)) of the coordinates z_(q) of the signal point of the 64QAM-UC defined in DVB-C.2.

FIG. 102 is a diagram illustrating a real part Re(z_(q)) of coordinates z_(q) of a signal point of 256QAM-UC (UC in 256QAM) defined in DVB-C.2. FIG. 103 is a diagram illustrating an imaginary part Im (z_(q)) of the coordinates z_(q) of the signal point of the 256QAM-UC defined in DVB-C.2.

FIG. 104 is a diagram illustrating a real part Re(z_(q)) of coordinates z_(q) of a signal point of 1024QAM-UC (UC in 1024QAM) defined in DVB-C.2. FIG. 105 is a diagram illustrating an imaginary part Im (z_(q)) of the coordinates z_(q) of the signal point of the 1024QAM-UC defined in DVB-C.2.

FIG. 106 is a diagram illustrating a real part Re(z_(q)) of coordinates z_(q) of a signal point of 4096QAM-UC (UC in 4096QAM) defined in DVB-C.2. FIG. 107 is a diagram illustrating an imaginary part Im (z_(q)) of the coordinates z_(q) of the signal point of the 4096QAM-UC signal point defined in DVB-C.2.

Note that, in FIGS. 96 to 107, y_(i,q) indicate the (i+1)-th bit from the lead of the m-bit (for example, 2 bits in QPSK) symbol of the 2^(m)QAM. In addition, the average power of the signal points on the constellation can be normalized in the transmission of (the data mapped to) the signal points of the UC. Assuming that P_(ave) indicates the root mean square of absolute values of all (the coordinates of) the signal points on the constellation, the normalization can be performed by multiplying each signal point z_(q) on the constellation by the reciprocal 1/(√P_(ave)) of the square root √P_(ave) the root mean square P_(ave).

In the transmission system of FIG. 7, the UC defined in DVB-C.2 as described above can be used.

That is, UC illustrated in FIGS. 96 to 107 can be used for each of new the LDPC codes (corresponding to the check matrix initial value table) with a code length N of 69120 bits and an encoding rate r of 2/16, 3/16, 4/16, 5/16, 6/16, 7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, and 14/16 illustrated in FIGS. 30 to 85.

FIGS. 108, 109, 110, 111, 112, 113A, 113B, 114, 115, and 116 are diagrams illustrating examples of the coordinates of another NUC signal point that can be used for each of the new LDPC codes with a code length N of 69120 bits and an encoding rate r of 2/16, 3/16, 4/16, 5/16, 6/16, 7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, 14/16 of FIGS. 30 to 85.

That is, FIG. 108 is a diagram illustrating an example of the coordinates of the signal point of the 16QAM-2D-NUC that can be used for each of the new LDPC codes with an encoding rate r(CR) of 2/16, 4/16, 6/16, 8/16, 10/16, 12/16, and 14/16 among the new LDPC codes with a code length N of 69120 of FIGS. 30 to 85.

FIG. 109 is a diagram illustrating an example of the coordinates of the signal point of the 64QAM-2D-NUC that can be used for each of the new LDPC codes with an encoding rate r(CR) of 3/16, 5/16, 7/16, 9/16, 11/16, and 13/16 among the new LDPC codes with a code length N of 69120 of FIGS. 30 to 85.

FIGS. 110 and 111 are diagrams illustrating examples of the coordinates of the signal point of the 256QAM-2D-NUC that can be used for each of the new LDPC codes with an encoding rate r(CR) of 2/16, 4/16, 6/16, 8/16, 10/16, 12/16, and 14/16 among the new LDPC codes with a code length N of 69120 of FIGS. 30 to 85.

Note that FIG. 111 is a diagram following FIG. 110.

In FIGS. 108 to 111, similarly to FIG. 93, the coordinates of the signal point z_(s) are expressed in the form of complex numbers, and j indicates an imaginary unit.

In FIGS. 108 to 111, similarly to FIG. 93, w #k indicates the coordinates of the signal point in the first quadrant of the constellation.

Herein, as described with reference to FIG. 93, an m-bit symbol is represented by an integer value of 0 to 2^(m)−1, and if b=2^(m)/4, the symbols y(0), y(1), . . . , and y(2^(m)−1) represented by an integer value of 0 to 2^(m)−1 can be classified into four of the symbols y (0) to y(b−1), the symbols y(b) to y(2b−1), the symbols y(2b) to y(3b−1), and the symbols y(3b) to y(4b−1).

In FIGS. 108 to 111, similarly to FIG. 93, the suffix k of w #k has an integer value in the range of 0 to b−1, and w #k indicates the coordinates of the signal point corresponding to the symbol y(k) in the range of the symbols y(0) to y(b−1).

Furthermore, in FIGS. 108 to 111, similarly to FIG. 93, the coordinates of the signal point corresponding to the symbol y(k+3b) in the range of the symbols y(3b) to y(4b−1) is indicated by −w #k.

However, in FIG. 93, the coordinates of the signal point corresponding to the symbol y(k+b) in the range of the symbols y(b) to y(2b−1) are indicated by −conj(w #k), and the coordinates of the signal point corresponding to the symbol y(k+2b) in the range from the symbol y(2b) to y(3b−1) are indicated by conj(w #k), but in FIGS. 108 to 111, the sign of conj is reversed.

That is, in FIGS. 108 to 111, the coordinates of the signal point corresponding to the symbol y(k+b) in the range of the symbols y(b) toy (2b−1) are indicated by conj (w #k), and the coordinates of the signal point corresponding to the symbol y (k+2b) in the range of the symbols y (2b) to y (3b−1) are indicated by −conj (w #k).

FIG. 112 is a diagram illustrating an example of the coordinates of the signal point of the 1024QAM-1D-NUC that can be used for each of the new LDPC codes with an encoding rate r(CR) of 3/16, 5/16, 7/16, 9/16, 11/16, and 13/16 among the new LDPC codes with a code length N of 69120 of FIGS. 30 to 85.

That is, FIG. 112 is a diagram illustrating a relationship between the real part Re (z_(s)) and the imaginary part Im (z_(s)) of the complex number as the coordinates of the signal point z_(s) of the 1024QAM-1D-NUC and (the components u #k of) the position vector u.

FIGS. 113A and 1138 are diagrams illustrating a relationship between the symbol y of the 1024QAM and (the components u #k of) the position vector u of FIG. 112.

That is, now, it is assumed that a 10-bit symbol y of the 1024QAM is indicated by y_(0,s), y_(1,s), y_(2,s), y_(3,s), y_(4,s), y_(5,s), y_(6,s), y_(7,s), y_(9,s), y_(9,s) from the leading bit (most significant bit) thereof.

FIG. 113A illustrates the correspondence between the odd-numbered 5 bits y_(0,s), y_(2,s), y_(4,s), y_(6,s), and y_(8,s) of the 10-bit symbol y and the position vector u #k indicating the real part Re(z_(s)) of (the coordinates of) the signal point z_(s) corresponding to the symbol y.

FIG. 113B illustrates the correspondence between the even-numbered 5 bits y_(1,s), y_(3,s), y_(5,s), y_(7,s), and y_(9,s) of the 10-bit symbol y and the position vector u #k indicating the imaginary part Im(z_(s)) of the signal point z_(s) corresponding to the symbol y.

The method of obtaining the coordinates of the signal point z_(s) when the 10-bit symbol y of the 1024QAM is mapped to the signal point z_(s) of the 1024QAM-1D-NUC defined in FIGS. 112, 113A and 113B is similar to that of the case described with reference to FIGS. 94, 95A, and 95B, and thus, the description thereof is omitted.

FIG. 114 is a diagram illustrating an example of the coordinates of the signal point of the 4096QAM-1D-NUC which can be used for each of the new LDPC codes with an encoding rate r of 2/16, 4/16, 6/16, 8/16, 10/16, 12/16, and 14/16 among the new LDPC codes with a code length N of 69120 bits of FIGS. 30 to 85.

That is, FIG. 114 is a diagram illustrating a relationship between the real part Re (z_(s)) and the imaginary part Im (z_(s)) of a complex number as coordinates of the signal point z_(s) of the 4096QAM-1D-NUC, and the position vector u (u #k).

FIGS. 115 and 116 are diagrams illustrating a relationship between the symbol y of 4096QAM and(the component su #k of) the position vector u of FIG. 114.

That is, now, The 12-bit symbols y of the 4096QAM are represented by y_(0,s), y_(1,s), y_(2,s), y_(3,s), y_(4,s), y_(5,s), y_(6,s), y_(7,s), y_(8,s), y_(9,s), y_(10,s), y_(11,s) from the bit (most significant bit) of the lead thereof.

FIG. 115 illustrates the correspondence between the odd-numbered 6 bits y_(0,s), y_(2,s), y_(4,s), y_(6,s), y_(8,s), and y_(10,s) of the 12-bit symbol y and the position vector u #k indicating the real part Re (z_(s)) of the signal point z_(s) corresponding to the symbol y.

FIG. 116 illustrates the correspondence between the even-numbered 6 bits y_(1,s), y_(3,s), y_(5,s), y_(7,s), y_(9,s), and y_(11,s) of the 12-bit symbol y and the position vector u #k indicating the imaginary part Im(z_(s)) of the signal point z_(s) corresponding to the symbol y.

The method of obtaining the coordinates of the signal point z_(s) when the 12-bit symbol y of the 4096QAM is mapped to the signal point z_(s) of the 4096QAM-1D-NUC defined in FIGS. 114 to 116 is similar to that of the case described with reference to FIGS. 94 and 95B, and thus, the description thereof is omitted.

In addition, the average power of the signal points on the constellation can be normalized in the transmission of (the data mapped to) the signal point of the NUC of FIGS. 108, 109, 110, 111, 112, 113A, 1138, 114, 115, and 116. Assuming that Pave indicates the root mean square of absolute values of all (the coordinates of) the signal points on the constellation, the normalization can be performed by multiplying each signal point z_(s) on the constellation by the reciprocal 1/(√_(Pave)) of the square root √_(Pave) of the root mean square _(Pave). In addition, in FIGS. 95A and 95B described above, the odd-numbered bits of the symbol y are associated with the position vector u #k indicating the imaginary part Im(z_(s)) of the signal point z_(s), and the even-numbered bits of the symbol y are associated with the position vector u #k indicating the real part Re(z_(s)) of the signal point z_(s). However, in FIGS. 113A 113B, 115, and 116, conversely, the odd-numbered bits of the symbol y are associated with the position vector u #k indicating the real part Re(z_(s)) of the signal point z_(s), and the even-numbered bits of the symbol y are associated with the position vector u #k indicating the imaginary part Im(z_(s)) of the signal point z_(s).

<Block Interleaver 25>

FIG. 117 is a diagram illustrating block interleaving performed by the block interleaver 25 of FIG. 9.

The block interleaving is performed by dividing the LDPC code of one code word into a portion called a Part 1 and a portion called a Part 2 from the lead thereof.

Assuming that the length (number of bits) of Part 1 is denoted by Npart1 and the length of Part 2 is denoted by Npart2, Npart1+Npart2 is equal to the code length N.

Conceptually, in the block interleaving, only the number of columns as a storage area for storing Npart1/m bits in the column (vertical) direction as one direction, which is equal to the number m of bits of symbols in the row direction perpendicular to the column direction, are arranged, and each column is divided into small units of 360 bits, which is the unit size P, from the top. The small unit of the column is also called a column unit.

In the block interleaving, as illustrated in FIG. 117, the writing of the Part 1 of an LDPC code of one code word in the downward direction (column direction) from the top of the first column unit of the column is performed in the column in the direction from the left to the right.

Then, when the writing to the first column unit of the rightmost column is completed, as illustrated in FIG. 117, the process returns to the leftmost column, and the writing in the downward direction from the top of the second column unit of the column is perform in the column in the direction from the left to the right. Hereinafter, in a similar manner, the writing of the Part 1 of the LDPC code of one code word is performed.

When the writing of the Part 1 of the LDPC code of one code word is completed, as illustrated in FIG. 117, the Part 1 of the LDPC code is read in units of m bits from the first row of all m columns in the row direction.

The m-bit unit of the Part 1 is supplied as an m-bit symbol from the block interleaver 25 to the mapper 117 (FIG. 8).

The reading of the Part 1 in units of m bits is sequentially performed toward the lower row of m columns, and when the reading of the Part 1 is completed, the Part 2 is divided in units of m bits from the lead, and symbols of m bits is supplied from the block interleaver 25 to the mapper 117.

Therefore, the Part 1 is symbolized while being interleaved, and the Part 2 is symbolized by being sequentially divided in units of m bits without being interleaved.

Npart1/m which is the length of the column is a multiple of 360 which is the unit size P, and the LDPC code of one code word is divided into the Part 1 and the Part 2 so that Npart1/m is a multiple of 360.

FIG. 118 is a diagram illustrating an example of a Part 1 and a Part 2 of an LDPC code with a code length N of 69120 bits in a case where the modulation scheme is QPSK, 16QAM, 64QAM, 256QAM, 1024QAM, and 4096QAM.

In FIG. 118, in a case where the modulation scheme is 1024QAM, the Part 1 is 68400 bits, and the Part 2 is 720 bits; and in a case where the modulation scheme is QPSK, 16QAM, 64QAM, 256QAM, or 4096QAM, in any case, the Part 1 is 69120 bits, and the Part 2 is 0 bits.

<Group-Wise Interleaving>

FIG. 119 is a diagram illustrating group-wise interleaving performed by the group-wise interleaver 24 in FIG. 9.

In the group-wise interleaving, as illustrated in FIG. 119, 360 bits of the one division obtained by dividing the LDPC codes of one code word in units of 360 bits which are equal to the unit size P from the lead thereof are set as a bit group, and the LDPC codes of one code word are interleaved in units of bit groups according to a predetermined pattern (hereinafter, also referred to as a GW pattern).

Herein, when the LDPC code of one code word is divided into the bit groups, an (i+1)-th bit group from the lead is hereinafter also referred to as a bit group i.

In a case where the unit size P is 360, for example, the LDPC code with a code length N of 1800 bits is divided into 5 (=1800/360) bit groups of the bit groups 0, 1, 2, 3, and 4. Furthermore, for example, the LDPC code with a code length N of 69120 bits is divided into 192 (=69120/360) bit groups of the bit groups 0, 1, . . . , and 191.

In addition, hereinafter, a GW pattern is indicated by an arrangement of numbers indicating a bit group. For example, for the LDPC code with a code length N of 1, 800 bits, for example, the GW patterns 4, 2, 0, 3, and 1 indicates interleaving (rearranging) the arrangement of the bit groups 0, 1, 2, 3, and 4 into the arrangement of the bit groups 4, 2, 0, 3, and 1.

For example, it is assumed that the (i+1)-th code bit from the lead of the LDPC code with a code length N of 1800 bits is indicated by xi.

In this case, according to the group-wise interleaving of the GW patterns 4, 2, 0, 3, and 1, the LDPC code {x₀, x₁, . . . , x₁₇₉₉} of 1800 bits is interleaved into {x₁₄₄₀, x₁₄₄₁, . . . , x₁₇₉₉}, {x₇₂₀, x₇₂₁, . . . , x₁₀₇₉}, {x₀, x₁, . . . , x₃₅₉}, {x₁₀₈₀, x₁₀₈₁, x₁₄₃₉}, and {x₃₆₀, x₃₆₁, . . . , x₇₁₉}.

The GW pattern can be set for each code length N of an LDPC code, each encoding rate r of an LDPC code, each modulation scheme, or each constellation or as a combination of two or more of the code length N, the encoding rate r, the modulation scheme, and the constellation.

<Example of GW Pattern for LDPC Code>

FIG. 120 is a diagram illustrating Example 1 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 120, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

12, 8, 132, 26, 3, 18, 19, 98, 37, 190, 123, 81, 95, 167, 76, 66, 27, 46, 105, 28, 29, 170, 20, 96, 35, 177, 24, 86, 114, 63, 52, 80, 119, 153, 121, 107, 97, 129, 57, 38, 15, 91, 122, 14, 104, 175, 150, 1, 124, 72, 90, 32, 161, 78, 44, 73, 134, 162, 5, 11, 179, 93, 6, 152, 180, 68, 36, 103, 160, 100, 138, 146, 9, 82, 187, 147, 7, 87, 17, 102, 69, 110, 130, 42, 16, 71, 2, 169, 58, 33, 136, 106, 140, 84, 79, 143, 156, 139, 55, 116, 4, 21, 144, 64, 70, 158, 48, 118, 184, 50, 181, 120, 174, 133, 115, 53, 127, 74, 25, 49, 88, 22, 89, 34, 126, 61, 94, 172, 131, 39, 99, 183, 163, 111, 155, 51, 191, 31, 128, 149, 56, 85, 109, 10, 151, 188, 40, 83, 41, 47, 178, 186, 43, 54, 164, 13, 142, 117, 92, 113, 182, 168, 165, 101, 171, 159, 60, 166, 77, 30, 67, 23, 0, 65, 141, 185, 112, 145, 135, 108, 176, 45, 148, 137, 125, 62, 75, 189, 59, 173, 154, 157.

FIG. 121 is a diagram illustrating Example 2 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 121, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

14, 119, 182, 5, 127, 21, 152, 11, 39, 164, 25, 69, 59, 140, 73, 9, 104, 148, 77, 44, 138, 89, 184, 35, 112, 150, 178, 26, 123, 133, 91, 76, 70, 0, 176, 118, 22, 147, 96, 108, 109, 139, 18, 157, 181, 126, 174, 179, 116, 38, 45, 158, 106, 168, 10, 97, 114, 129, 180, 52, 7, 67, 43, 50, 120, 122, 3, 13, 72, 185, 34, 83, 124, 105, 162, 87, 131, 155, 135, 42, 64, 165, 41, 71, 189, 159, 143, 102, 153, 17, 24, 30, 66, 137, 62, 55, 48, 98, 110, 40, 121, 187, 74, 92, 60, 101, 57, 33, 130, 173, 32, 166, 128, 54, 99, 111, 100, 16, 84, 132, 161, 4, 190, 49, 95, 141, 28, 85, 61, 53, 183, 6, 68, 2, 163, 37, 103, 186, 154, 171, 170, 78, 117, 93, 8, 145, 51, 56, 191, 90, 82, 151, 115, 175, 1, 125, 79, 20, 80, 36, 169, 46, 167, 63, 177, 149, 81, 12, 156, 142, 31, 47, 88, 65, 134, 94, 86, 160, 172, 19, 23, 136, 58, 146, 15, 75, 107, 188, 29, 113, 144, 27.

FIG. 122 is a diagram illustrating Example 3 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 122, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

121, 28, 49, 4, 21, 191, 90, 101, 188, 126, 8, 131, 81, 150, 141, 152, 17, 82, 61, 119, 125, 145, 153, 45, 108, 22, 94, 48, 29, 12, 59, 140, 75, 169, 183, 157, 142, 158, 113, 79, 89, 186, 112, 80, 56, 120, 166, 15, 43, 2, 62, 115, 38, 123, 73, 179, 155, 171, 185, 5, 168, 172, 190, 106, 174, 96, 116, 91, 30, 147, 19, 149, 37, 175, 124, 156, 14, 144, 86, 110, 40, 68, 162, 66, 130, 74, 165, 180, 13, 177, 122, 23, 109, 95, 42, 117, 65, 3, 111, 18, 32, 52, 97, 184, 54, 46, 167, 136, 1, 134, 189, 187, 16, 36, 84, 132, 170, 34, 57, 24, 137, 100, 39, 127, 6, 102, 10, 25, 114, 146, 53, 99, 85, 35, 78, 148, 9, 143, 139, 92, 173, 27, 11, 26, 104, 176, 98, 129, 51, 103, 160, 71, 154, 118, 67, 33, 181, 87, 77, 47, 159, 178, 83, 70, 164, 44, 69, 88, 63, 161, 182, 133, 20, 41, 64, 76, 31, 50, 128, 105, 0, 135, 55, 72, 93, 151, 107, 163, 60, 138, 7, 58.

FIG. 123 is a diagram illustrating Example 4 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 123, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

99, 59, 95, 50, 122, 15, 144, 6, 129, 36, 175, 159, 165, 35, 182, 181, 189, 29, 2, 115, 91, 41, 60, 160, 51, 106, 168, 173, 20, 138, 183, 70, 24, 127, 47, 5, 119, 171, 102, 135, 116, 156, 120, 105, 117, 136, 149, 128, 85, 46, 186, 113, 73, 103, 52, 82, 89, 184, 22, 185, 155, 125, 133, 37, 27, 10, 137, 76, 12, 98, 148, 109, 42, 16, 190, 84, 94, 97, 25, 11, 88, 166, 131, 48, 161, 65, 9, 8, 58, 56, 124, 68, 54, 3, 169, 146, 87, 108, 110, 121, 163, 57, 90, 100, 66, 49, 61, 178, 18, 7, 28, 67, 13, 32, 34, 86, 153, 112, 63, 43, 164, 132, 118, 93, 38, 39, 17, 154, 170, 81, 141, 191, 152, 111, 188, 147, 180, 75, 72, 26, 177, 126, 179, 55, 1, 143, 45, 21, 40, 123, 23, 162, 77, 62, 134, 158, 176, 31, 69, 114, 142, 19, 96, 101, 71, 30, 140, 187, 92, 80, 79, 0, 104, 53, 145, 139, 14, 33, 74, 157, 150, 44, 172, 151, 64, 78, 130, 83, 167, 4, 107, 174.

FIG. 124 is a diagram illustrating Example 5 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 124, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

170, 45, 67, 94, 110, 153, 19, 38, 112, 176, 49, 138, 35, 114, 184, 159, 17, 41, 47, 189, 65, 125, 154, 57, 83, 6, 97, 167, 51, 59, 23, 81, 54, 46, 168, 178, 148, 5, 122, 129, 155, 179, 95, 102, 8, 119, 29, 113, 14, 60, 43, 66, 55, 103, 111, 88, 56, 7, 118, 63, 134, 108, 61, 187, 124, 31, 133, 22, 79, 52, 36, 144, 89, 177, 40, 116, 121, 135, 163, 92, 117, 162, 149, 106, 173, 181, 11, 164, 185, 99, 18, 158, 16, 12, 48, 9, 123, 147, 145, 169, 130, 183, 28, 151, 71, 126, 69, 165, 21, 13, 15, 62, 80, 182, 76, 90, 180, 50, 127, 131, 109, 3, 115, 120, 161, 82, 34, 78, 128, 142, 136, 75, 86, 137, 26, 25, 44, 91, 42, 73, 140, 146, 152, 27, 101, 93, 20, 166, 171, 100, 70, 84, 53, 186, 24, 98, 4, 37, 141, 190, 68, 150, 1, 72, 39, 87, 188, 191, 156, 33, 30, 160, 143, 64, 132, 77, 0, 58, 174, 157, 105, 175, 10, 172, 104, 2, 96, 139, 32, 85, 107, 74.

FIG. 125 is a diagram illustrating Example 6 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 125, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

111, 156, 189, 11, 132, 114, 100, 154, 77, 79, 95, 161, 47, 142, 36, 98, 3, 125, 159, 120, 40, 160, 29, 153, 16, 39, 101, 58, 191, 46, 76, 4, 183, 176, 62, 60, 74, 7, 37, 127, 19, 186, 71, 50, 139, 27, 188, 113, 38, 130, 124, 26, 146, 131, 102, 110, 105, 147, 86, 150, 94, 162, 175, 88, 104, 55, 89, 181, 34, 69, 22, 92, 133, 1, 25, 0, 158, 10, 24, 116, 164, 165, 112, 72, 106, 129, 81, 66, 54, 49, 136, 118, 83, 41, 2, 56, 145, 28, 177, 168, 117, 9, 157, 173, 115, 149, 42, 103, 14, 84, 155, 187, 99, 6, 43, 70, 140, 73, 32, 78, 75, 167, 148, 48, 134, 178, 59, 15, 63, 91, 82, 33, 135, 166, 190, 152, 96, 137, 12, 182, 61, 107, 128, 119, 179, 45, 184, 65, 172, 138, 31, 57, 174, 17, 180, 5, 30, 170, 23, 85, 185, 35, 44, 123, 90, 20, 122, 8, 64, 141, 169, 121, 97, 108, 80, 171, 18, 13, 87, 163, 109, 52, 51, 21, 93, 67, 126, 68, 53, 143, 144, 151.

FIG. 126 is a diagram illustrating Example 7 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 126, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191.

FIG. 127 is a diagram illustrating Example 8 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 127, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191.

FIG. 128 is a diagram illustrating Example 9 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 128, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191.

FIG. 129 is a diagram illustrating Example 10 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 129, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191.

FIG. 130 is a diagram illustrating Example 11 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 130, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191.

FIG. 131 is a diagram illustrating Example 12 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 131, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191.

FIG. 132 is a diagram illustrating Example 13 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 132, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191.

FIG. 133 is a diagram illustrating Example 14 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 133, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

154, 106, 99, 177, 191, 55, 189, 181, 22, 62, 80, 114, 110, 141, 83, 103, 169, 156, 130, 186, 92, 45, 68, 126, 112, 185, 160, 158, 17, 145, 162, 127, 152, 174, 134, 18, 157, 120, 3, 29, 13, 135, 173, 86, 73, 150, 46, 153, 33, 61, 142, 102, 171, 168, 78, 77, 139, 85, 176, 163, 128, 101, 42, 2, 14, 38, 10, 125, 90, 30, 63, 172, 47, 108, 89, 0, 32, 94, 23, 34, 59, 35, 129, 12, 146, 8, 60, 27, 147, 180, 100, 87, 184, 167, 36, 79, 138, 4, 95, 148, 72, 54, 91, 182, 28, 133, 164, 175, 123, 107, 137, 88, 44, 116, 69, 7, 31, 124, 144, 105, 170, 6, 165, 15, 161, 24, 58, 70, 11, 56, 143, 111, 104, 74, 67, 109, 82, 21, 52, 9, 71, 48, 26, 117, 50, 149, 140, 20, 57, 136, 113, 64, 151, 190, 131, 19, 51, 96, 76, 1, 97, 40, 53, 84, 166, 75, 159, 98, 81, 49, 66, 188, 118, 39, 132, 187, 25, 119, 41, 122, 16, 5, 93, 115, 178, 65, 121, 37, 155, 183, 43, 179.

FIG. 134 is a diagram illustrating Example 15 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 134, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

1, 182, 125, 0, 121, 47, 63, 154, 76, 99, 82, 163, 102, 166, 28, 189, 56, 67, 54, 39, 40, 185, 184, 65, 179, 4, 91, 87, 137, 170, 98, 71, 169, 49, 73, 37, 11, 143, 150, 123, 93, 62, 3, 50, 26, 140, 178, 95, 183, 33, 21, 53, 112, 128, 118, 120, 106, 139, 32, 130, 173, 132, 156, 119, 83, 176, 159, 13, 145, 36, 30, 113, 2, 41, 147, 174, 94, 88, 92, 60, 165, 59, 25, 161, 100, 85, 81, 61, 138, 48, 177, 77, 6, 22, 16, 43, 115, 23, 12, 66, 70, 9, 164, 122, 58, 105, 69, 42, 38, 19, 24, 180, 175, 74, 160, 34, 101, 72, 114, 142, 20, 8, 15, 190, 144, 104, 79, 172, 148, 31, 168, 10, 107, 14, 35, 52, 134, 126, 167, 149, 116, 186, 17, 162, 151, 5, 136, 55, 44, 110, 158, 46, 191, 29, 153, 155, 117, 188, 131, 97, 146, 103, 78, 109, 129, 57, 111, 45, 68, 157, 84, 141, 89, 64, 7, 108, 152, 75, 18, 96, 133, 171, 86, 181, 127, 27, 124, 187, 135, 80, 51, 90.

FIG. 135 is a diagram illustrating Example 16 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 135, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

35, 75, 166, 145, 143, 184, 62, 96, 54, 63, 157, 103, 32, 43, 126, 187, 144, 91, 78, 44, 39, 109, 185, 102, 10, 68, 29, 42, 149, 83, 133, 94, 130, 27, 171, 19, 51, 165, 148, 28, 36, 33, 173, 136, 87, 82, 100, 49, 120, 152, 161, 162, 147, 71, 137, 57, 8, 53, 132, 151, 163, 123, 47, 92, 90, 60, 99, 79, 59, 108, 115, 72, 0, 12, 140, 160, 61, 180, 74, 37, 86, 117, 191, 101, 52, 15, 80, 156, 127, 81, 131, 141, 142, 31, 95, 4, 73, 64, 16, 18, 146, 70, 181, 7, 89, 124, 77, 67, 116, 21, 34, 41, 105, 113, 97, 2, 6, 55, 17, 65, 38, 48, 158, 159, 179, 5, 30, 183, 170, 135, 125, 20, 106, 186, 182, 188, 114, 1, 14, 3, 134, 178, 189, 167, 40, 119, 22, 190, 58, 23, 155, 138, 98, 84, 11, 110, 88, 46, 177, 175, 25, 150, 118, 121, 129, 168, 13, 128, 104, 69, 112, 169, 9, 45, 174, 93, 26, 56, 76, 50, 154, 139, 66, 85, 153, 107, 111, 172, 176, 164, 24, 122.

FIG. 136 is a diagram illustrating Example 17 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 136, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

155, 188, 123, 132, 15, 79, 59, 119, 66, 68, 41, 175, 184, 78, 142, 32, 54, 111, 139, 134, 95, 34, 161, 150, 58, 141, 74, 112, 121, 99, 178, 179, 57, 90, 80, 21, 11, 29, 67, 104, 52, 87, 38, 81, 181, 160, 176, 16, 71, 13, 186, 171, 9, 170, 2, 177, 0, 88, 149, 190, 69, 33, 183, 146, 61, 117, 113, 6, 96, 120, 162, 23, 53, 140, 91, 128, 46, 93, 174, 126, 159, 133, 8, 152, 103, 102, 151, 143, 100, 4, 180, 166, 55, 164, 18, 49, 62, 20, 83, 7, 187, 153, 64, 37, 144, 185, 19, 114, 25, 116, 12, 173, 122, 127, 89, 115, 75, 101, 189, 124, 157, 108, 28, 165, 163, 65, 168, 77, 82, 27, 137, 86, 22, 110, 63, 148, 158, 97, 31, 105, 135, 98, 44, 70, 182, 191, 17, 156, 129, 39, 136, 169, 3, 145, 154, 109, 76, 5, 10, 106, 35, 94, 172, 45, 51, 60, 42, 50, 72, 85, 40, 118, 36, 14, 130, 131, 138, 43, 48, 125, 84, 24, 26, 1, 56, 107, 92, 147, 47, 30, 73, 167.

FIG. 137 is a diagram illustrating Example 18 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 137, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

152, 87, 170, 33, 48, 95, 2, 184, 145, 51, 94, 164, 38, 90, 158, 70, 124, 128, 66, 111, 79, 42, 45, 141, 83, 73, 57, 119, 20, 67, 31, 179, 123, 183, 26, 188, 15, 163, 1, 133, 105, 72, 81, 153, 69, 182, 101, 180, 185, 190, 77, 6, 127, 138, 75, 59, 24, 175, 30, 186, 139, 56, 100, 176, 147, 189, 116, 131, 25, 5, 16, 117, 74, 50, 171, 114, 76, 44, 107, 135, 71, 181, 13, 43, 122, 78, 4, 58, 35, 63, 187, 98, 37, 169, 148, 7, 10, 49, 80, 161, 167, 28, 142, 46, 97, 92, 121, 112, 88, 102, 106, 173, 19, 27, 41, 172, 91, 191, 34, 118, 108, 136, 166, 155, 96, 3, 165, 103, 84, 109, 104, 53, 23, 0, 178, 17, 86, 9, 168, 134, 110, 18, 32, 146, 129, 159, 55, 154, 126, 40, 151, 174, 60, 52, 22, 149, 156, 113, 143, 11, 93, 62, 177, 64, 61, 160, 150, 65, 130, 82, 29, 115, 137, 36, 8, 157, 54, 89, 99, 120, 68, 21, 140, 14, 39, 132, 125, 12, 85, 162, 47, 144.

FIG. 138 is a diagram illustrating Example 19 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 138, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

140, 8, 176, 13, 41, 165, 27, 109, 121, 153, 58, 181, 143, 164, 103, 115, 91, 66, 60, 189, 101, 4, 14, 102, 45, 124, 104, 159, 130, 133, 135, 77, 25, 59, 180, 141, 144, 62, 114, 182, 134, 148, 11, 20, 125, 83, 162, 75, 126, 67, 9, 178, 171, 152, 166, 69, 174, 15, 80, 168, 131, 95, 56, 48, 63, 82, 147, 51, 108, 52, 30, 139, 22, 37, 173, 112, 191, 98, 116, 149, 167, 142, 29, 154, 92, 94, 71, 117, 79, 122, 129, 24, 81, 105, 97, 137, 128, 1, 113, 170, 119, 7, 158, 76, 19, 183, 68, 31, 50, 118, 33, 72, 55, 65, 146, 185, 111, 145, 28, 21, 177, 160, 32, 61, 70, 106, 156, 78, 132, 88, 184, 35, 5, 53, 138, 47, 100, 10, 42, 36, 175, 93, 120, 190, 16, 123, 87, 54, 186, 18, 57, 84, 99, 12, 163, 157, 188, 64, 38, 26, 2, 136, 40, 169, 90, 107, 46, 172, 49, 6, 39, 44, 150, 85, 0, 17, 127, 155, 110, 34, 96, 74, 86, 187, 89, 151, 43, 179, 161, 73, 23, 3.

FIG. 139 is a diagram illustrating Example 20 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 139, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

10, 61, 30, 88, 33, 60, 1, 102, 45, 103, 119, 181, 82, 112, 12, 67, 69, 171, 108, 26, 145, 156, 81, 152, 8, 16, 68, 13, 99, 183, 146, 27, 158, 147, 132, 118, 180, 120, 173, 59, 186, 49, 7, 17, 35, 104, 129, 75, 54, 72, 18, 48, 15, 177, 191, 51, 24, 93, 106, 22, 71, 29, 141, 32, 143, 128, 175, 86, 190, 74, 36, 43, 144, 46, 63, 65, 133, 31, 87, 44, 20, 117, 76, 187, 80, 101, 151, 47, 130, 116, 162, 127, 153, 100, 94, 2, 41, 138, 125, 131, 11, 50, 40, 21, 184, 167, 172, 85, 160, 105, 73, 38, 157, 53, 39, 97, 107, 165, 168, 89, 148, 126, 3, 4, 114, 161, 155, 182, 136, 149, 111, 98, 113, 139, 92, 109, 174, 185, 95, 56, 135, 37, 163, 154, 0, 96, 78, 122, 5, 179, 140, 83, 123, 77, 9, 19, 66, 42, 137, 14, 23, 159, 189, 110, 142, 84, 169, 166, 52, 91, 164, 28, 124, 121, 70, 115, 90, 170, 58, 6, 178, 176, 64, 188, 57, 34, 79, 62, 25, 134, 150, 55.

FIG. 140 is a diagram illustrating Example 21 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 140, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

8, 165, 180, 182, 189, 61, 7, 140, 105, 78, 86, 75, 15, 28, 82, 1, 136, 130, 35, 24, 70, 152, 121, 11, 36, 66, 83, 57, 164, 111, 137, 128, 175, 156, 151, 48, 44, 147, 18, 64, 184, 42, 159, 3, 6, 162, 170, 98, 101, 29, 102, 21, 188, 79, 138, 45, 124, 118, 155, 125, 34, 27, 5, 97, 109, 145, 54, 56, 126, 187, 16, 149, 160, 178, 23, 141, 30, 117, 25, 69, 116, 131, 94, 65, 191, 99, 181, 185, 115, 67, 93, 106, 38, 71, 76, 113, 132, 172, 103, 95, 92, 107, 4, 163, 139, 72, 157, 0, 12, 52, 68, 88, 161, 183, 39, 14, 32, 49, 19, 77, 174, 47, 154, 17, 134, 133, 51, 120, 74, 177, 41, 108, 142, 143, 13, 26, 59, 100, 123, 55, 158, 62, 104, 148, 135, 9, 179, 53, 176, 33, 169, 129, 186, 43, 167, 87, 119, 84, 90, 150, 20, 10, 122, 114, 80, 50, 146, 144, 96, 171, 40, 73, 81, 168, 112, 190, 37, 173, 46, 110, 60, 85, 153, 2, 63, 91, 127, 89, 31, 58, 22, 166.

FIG. 141 is a diagram illustrating Example 22 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 141, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

17, 84, 125, 70, 134, 63, 68, 162, 61, 31, 74, 137, 7, 138, 5, 60, 76, 105, 160, 12, 114, 81, 155, 112, 153, 191, 82, 148, 118, 108, 58, 159, 43, 161, 149, 96, 71, 30, 145, 174, 67, 77, 47, 94, 48, 156, 151, 141, 131, 176, 183, 41, 35, 83, 164, 55, 169, 98, 187, 124, 100, 54, 104, 40, 2, 72, 8, 85, 182, 103, 6, 37, 107, 39, 42, 123, 57, 106, 13, 150, 129, 46, 109, 188, 45, 113, 44, 90, 20, 165, 142, 110, 22, 28, 173, 38, 52, 16, 34, 0, 3, 144, 27, 49, 139, 177, 132, 184, 25, 87, 152, 119, 158, 78, 186, 167, 97, 24, 99, 69, 120, 122, 133, 163, 21, 51, 101, 185, 111, 26, 18, 10, 33, 170, 95, 65, 14, 130, 157, 59, 115, 127, 92, 56, 1, 80, 66, 126, 178, 147, 75, 179, 171, 53, 146, 88, 4, 128, 121, 86, 117, 19, 23, 168, 181, 11, 102, 93, 73, 140, 89, 136, 9, 180, 62, 36, 79, 91, 190, 143, 29, 154, 32, 64, 166, 116, 15, 189, 175, 50, 135, 172.

FIG. 142 is a diagram illustrating Example 23 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 142, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

157, 20, 116, 115, 49, 178, 148, 152, 174, 130, 171, 81, 60, 146, 182, 72, 46, 22, 93, 101, 9, 55, 40, 163, 118, 30, 52, 181, 151, 31, 87, 117, 120, 82, 95, 190, 23, 36, 67, 62, 14, 167, 80, 27, 24, 43, 94, 0, 63, 5, 74, 78, 158, 88, 84, 109, 147, 112, 124, 110, 21, 47, 45, 68, 184, 70, 1, 66, 149, 105, 140, 170, 56, 98, 135, 61, 79, 123, 166, 185, 41, 108, 122, 92, 16, 26, 37, 177, 173, 113, 136, 89, 162, 85, 54, 39, 73, 58, 131, 134, 188, 127, 3, 164, 13, 132, 129, 179, 25, 18, 57, 32, 119, 111, 53, 155, 28, 107, 133, 144, 19, 160, 71, 186, 153, 103, 2, 12, 91, 106, 64, 175, 75, 189, 128, 142, 187, 76, 180, 34, 59, 169, 90, 11, 172, 97, 141, 38, 191, 17, 114, 126, 145, 83, 143, 125, 121, 10, 44, 137, 86, 29, 104, 154, 168, 65, 159, 15, 99, 35, 50, 48, 138, 96, 100, 102, 7, 42, 156, 8, 4, 69, 183, 51, 165, 6, 150, 77, 161, 33, 176, 139.

FIG. 143 is a diagram illustrating Example 24 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 143, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

42, 168, 36, 37, 152, 118, 14, 83, 105, 131, 26, 120, 92, 130, 158, 132, 49, 72, 137, 100, 88, 24, 53, 142, 110, 102, 74, 188, 113, 121, 12, 173, 5, 126, 127, 3, 93, 46, 164, 109, 151, 2, 98, 153, 116, 89, 101, 136, 35, 80, 0, 133, 183, 162, 185, 56, 17, 87, 117, 184, 54, 70, 176, 91, 134, 51, 38, 73, 165, 99, 169, 43, 167, 86, 11, 144, 78, 58, 64, 13, 119, 33, 166, 6, 75, 31, 15, 28, 125, 148, 27, 114, 82, 45, 55, 191, 160, 115, 1, 69, 187, 122, 177, 32, 172, 52, 112, 171, 124, 180, 85, 150, 7, 57, 60, 94, 181, 29, 97, 128, 19, 149, 175, 50, 140, 10, 174, 68, 59, 39, 106, 44, 62, 71, 18, 107, 156, 159, 146, 48, 81, 111, 96, 103, 34, 161, 141, 154, 76, 61, 135, 20, 84, 77, 108, 23, 145, 182, 170, 139, 157, 47, 9, 63, 123, 138, 155, 79, 4, 30, 143, 25, 90, 66, 147, 186, 179, 129, 21, 65, 41, 95, 67, 22, 163, 190, 16, 8, 104, 189, 40, 178.

FIG. 144 is a diagram illustrating Example 25 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 144, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

92, 132, 39, 44, 190, 21, 70, 146, 48, 13, 17, 187, 119, 43, 94, 157, 150, 98, 96, 47, 86, 63, 152, 158, 84, 170, 81, 7, 62, 191, 174, 99, 116, 10, 85, 113, 135, 28, 53, 122, 83, 141, 77, 23, 131, 4, 40, 168, 129, 109, 51, 130, 188, 147, 29, 50, 26, 78, 148, 164, 167, 103, 36, 134, 2, 177, 20, 123, 27, 90, 176, 5, 33, 133, 189, 138, 76, 41, 89, 35, 72, 139, 32, 73, 68, 67, 101, 166, 93, 54, 52, 42, 110, 59, 8, 179, 34, 171, 143, 137, 9, 126, 155, 108, 142, 120, 163, 12, 3, 75, 159, 107, 65, 128, 87, 6, 22, 57, 100, 24, 64, 106, 117, 19, 58, 95, 74, 180, 125, 136, 186, 154, 121, 161, 88, 37, 114, 102, 105, 160, 80, 185, 82, 124, 184, 15, 16, 18, 118, 173, 151, 11, 91, 79, 46, 140, 127, 1, 169, 0, 61, 66, 45, 162, 149, 115, 144, 30, 25, 175, 153, 183, 60, 38, 31, 111, 182, 49, 55, 145, 56, 181, 104, 14, 71, 178, 112, 172, 165, 69, 97, 156.

FIG. 145 is a diagram illustrating Example 26 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 145, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

133, 96, 46, 148, 78, 109, 149, 161, 55, 39, 183, 54, 186, 73, 150, 180, 189, 190, 22, 135, 12, 80, 42, 130, 164, 70, 126, 107, 57, 67, 15, 157, 52, 88, 5, 23, 123, 66, 53, 147, 177, 60, 131, 108, 171, 191, 44, 140, 98, 154, 37, 118, 176, 92, 124, 138, 132, 167, 173, 13, 79, 32, 145, 14, 113, 30, 2, 0, 165, 182, 153, 24, 144, 87, 82, 75, 141, 89, 137, 33, 100, 106, 128, 168, 29, 36, 172, 11, 111, 68, 16, 10, 34, 188, 35, 160, 77, 83, 178, 58, 59, 7, 56, 110, 104, 61, 76, 85, 121, 93, 19, 134, 179, 155, 163, 115, 185, 125, 112, 71, 8, 119, 18, 47, 151, 26, 103, 122, 9, 170, 146, 99, 49, 72, 102, 31, 40, 43, 158, 142, 4, 69, 139, 28, 174, 101, 84, 129, 156, 74, 62, 91, 159, 41, 38, 45, 136, 169, 21, 51, 181, 97, 166, 175, 90, 27, 86, 65, 105, 143, 127, 17, 6, 116, 94, 117, 48, 50, 25, 64, 95, 63, 184, 152, 120, 1, 187, 162, 114, 3, 81, 20.

FIG. 146 is a diagram illustrating Example 27 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 146, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

59, 34, 129, 18, 137, 6, 83, 139, 47, 148, 147, 110, 11, 98, 62, 149, 158, 14, 42, 180, 23, 128, 99, 181, 54, 176, 35, 130, 53, 179, 39, 152, 32, 52, 69, 82, 84, 113, 79, 21, 95, 7, 126, 191, 86, 169, 111, 12, 55, 27, 182, 120, 123, 88, 107, 50, 144, 49, 38, 165, 0, 159, 10, 43, 114, 187, 150, 19, 65, 48, 124, 8, 141, 171, 173, 17, 167, 92, 74, 170, 184, 67, 33, 172, 16, 119, 66, 57, 89, 106, 26, 78, 178, 109, 70, 2, 157, 15, 105, 22, 174, 127, 100, 71, 97, 163, 9, 77, 87, 41, 183, 117, 46, 40, 131, 85, 136, 72, 122, 1, 45, 13, 44, 56, 61, 146, 25, 132, 177, 76, 121, 160, 112, 5, 134, 73, 91, 135, 68, 3, 80, 90, 190, 60, 75, 145, 115, 81, 161, 156, 116, 166, 96, 28, 138, 94, 162, 140, 102, 4, 133, 30, 155, 189, 143, 64, 185, 164, 104, 142, 154, 118, 24, 31, 153, 103, 51, 108, 29, 37, 58, 186, 175, 36, 151, 63, 93, 188, 125, 101, 20, 168.

FIG. 147 is a diagram illustrating Example 28 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 147, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

61, 110, 123, 127, 148, 162, 131, 71, 176, 22, 157, 0, 151, 155, 112, 189, 36, 181, 10, 46, 133, 75, 80, 88, 6, 165, 97, 54, 31, 174, 49, 139, 98, 4, 170, 26, 50, 16, 141, 187, 13, 109, 106, 120, 72, 32, 63, 59, 79, 172, 83, 100, 92, 24, 56, 130, 167, 81, 103, 111, 158, 159, 153, 175, 8, 41, 136, 70, 33, 45, 84, 150, 39, 166, 164, 99, 126, 190, 134, 40, 87, 64, 154, 140, 116, 184, 115, 183, 30, 35, 7, 42, 146, 86, 58, 12, 14, 149, 89, 179, 128, 160, 95, 171, 74, 25, 29, 119, 143, 178, 28, 21, 23, 90, 188, 96, 173, 93, 147, 191, 18, 62, 2, 132, 20, 11, 17, 135, 152, 67, 73, 108, 76, 91, 156, 104, 48, 121, 94, 125, 38, 65, 177, 68, 37, 124, 78, 118, 186, 34, 185, 113, 169, 9, 69, 82, 163, 114, 145, 168, 44, 52, 105, 51, 137, 1, 161, 3, 55, 182, 101, 57, 43, 77, 5, 47, 144, 180, 66, 53, 19, 117, 60, 138, 142, 107, 122, 85, 27, 129, 15, 102.

FIG. 148 is a diagram illustrating Example 29 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 148, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

8, 174, 121, 46, 70, 106, 183, 9, 96, 109, 72, 130, 47, 168, 1, 190, 18, 90, 103, 135, 105, 112, 23, 33, 185, 31, 171, 111, 0, 115, 4, 159, 25, 65, 134, 146, 26, 37, 16, 169, 167, 74, 67, 155, 154, 83, 117, 53, 19, 161, 76, 12, 7, 131, 59, 51, 189, 42, 114, 142, 126, 66, 164, 191, 55, 132, 35, 153, 137, 87, 5, 100, 122, 150, 2, 49, 32, 172, 149, 177, 15, 82, 98, 34, 140, 170, 56, 78, 188, 57, 118, 186, 181, 52, 71, 24, 81, 22, 11, 156, 86, 148, 97, 38, 48, 64, 40, 165, 180, 125, 127, 143, 88, 43, 61, 158, 28, 162, 187, 110, 84, 157, 27, 41, 39, 124, 85, 58, 20, 44, 102, 36, 77, 147, 120, 179, 21, 60, 92, 138, 119, 173, 160, 144, 91, 99, 107, 101, 145, 184, 108, 95, 69, 63, 3, 89, 128, 136, 94, 129, 50, 79, 68, 151, 104, 163, 123, 182, 93, 29, 133, 152, 178, 80, 62, 54, 14, 141, 166, 176, 45, 30, 10, 6, 75, 73, 116, 175, 17, 113, 139, 13.

FIG. 149 is a diagram illustrating Example 30 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 149, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

179, 91, 101, 128, 169, 69, 185, 35, 156, 168, 132, 163, 46, 28, 5, 41, 162, 112, 108, 130, 153, 79, 118, 102, 125, 176, 71, 20, 115, 98, 124, 75, 103, 21, 164, 173, 9, 36, 56, 134, 24, 16, 159, 34, 15, 42, 104, 54, 120, 76, 60, 33, 127, 88, 133, 137, 61, 19, 3, 170, 87, 190, 13, 141, 188, 106, 113, 67, 145, 146, 111, 74, 89, 62, 175, 49, 32, 99, 93, 107, 171, 66, 80, 155, 100, 152, 4, 10, 126, 109, 181, 154, 105, 48, 136, 161, 183, 97, 31, 12, 8, 184, 47, 142, 18, 14, 117, 73, 84, 70, 68, 0, 23, 96, 165, 29, 122, 81, 17, 131, 44, 157, 26, 25, 189, 83, 178, 37, 123, 82, 191, 39, 7, 72, 160, 64, 143, 149, 138, 65, 58, 119, 63, 166, 114, 95, 172, 43, 140, 57, 158, 186, 86, 174, 92, 45, 139, 144, 147, 148, 151, 59, 30, 85, 40, 51, 187, 78, 38, 150, 129, 121, 27, 94, 52, 177, 110, 182, 55, 22, 167, 90, 77, 6, 11, 1, 116, 53, 2, 50, 135, 180.

FIG. 150 is a diagram illustrating Example 31 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 150, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

99, 59, 95, 50, 122, 15, 144, 6, 129, 36, 175, 159, 165, 35, 182, 181, 189, 29, 2, 115, 91, 41, 60, 160, 51, 106, 168, 173, 20, 138, 183, 70, 24, 127, 47, 5, 119, 171, 102, 135, 116, 156, 120, 105, 117, 136, 149, 128, 85, 46, 186, 113, 73, 103, 52, 82, 89, 184, 22, 185, 155, 125, 133, 37, 27, 10, 137, 76, 12, 98, 148, 109, 42, 16, 190, 84, 94, 97, 25, 11, 88, 166, 131, 48, 161, 65, 9, 8, 58, 56, 124, 68, 54, 3, 169, 146, 87, 108, 110, 121, 163, 57, 90, 100, 66, 49, 61, 178, 18, 7, 28, 67, 13, 32, 34, 86, 153, 112, 63, 43, 164, 132, 118, 93, 38, 39, 17, 154, 170, 81, 141, 191, 152, 111, 188, 147, 180, 75, 72, 26, 177, 126, 179, 55, 1, 143, 45, 21, 40, 123, 23, 162, 77, 62, 134, 158, 176, 31, 69, 114, 142, 19, 96, 101, 71, 30, 140, 187, 92, 80, 79, 0, 104, 53, 145, 139, 14, 33, 74, 157, 150, 44, 172, 151, 64, 78, 130, 83, 167, 4, 107, 174.

FIG. 151 is a diagram illustrating Example 32 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 151, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

16, 133, 14, 114, 145, 191, 53, 80, 166, 68, 21, 184, 73, 165, 147, 89, 180, 55, 135, 94, 189, 78, 103, 115, 72, 24, 105, 188, 84, 148, 85, 32, 1, 131, 34, 134, 41, 167, 81, 54, 142, 141, 75, 155, 122, 140, 13, 17, 8, 23, 61, 49, 51, 74, 181, 162, 143, 42, 71, 123, 161, 177, 110, 149, 126, 0, 63, 178, 35, 175, 186, 52, 43, 139, 112, 10, 40, 150, 182, 164, 64, 83, 174, 38, 47, 30, 2, 116, 25, 128, 160, 144, 99, 5, 187, 176, 82, 60, 18, 185, 104, 169, 39, 183, 137, 22, 109, 96, 151, 46, 33, 29, 65, 132, 95, 31, 136, 159, 170, 168, 67, 79, 93, 111, 90, 97, 113, 92, 76, 58, 127, 26, 27, 156, 3, 6, 28, 77, 125, 173, 98, 138, 172, 86, 45, 118, 171, 62, 179, 100, 19, 163, 50, 57, 56, 36, 102, 121, 117, 154, 119, 66, 20, 91, 130, 69, 44, 70, 153, 152, 158, 88, 108, 12, 59, 4, 11, 120, 87, 101, 37, 129, 146, 9, 106, 48, 7, 15, 124, 190, 107, 157.

FIG. 152 is a diagram illustrating Example 33 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 152, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

178, 39, 54, 68, 122, 20, 86, 137, 156, 55, 52, 72, 130, 152, 147, 12, 69, 48, 107, 44, 88, 23, 181, 174, 124, 81, 59, 93, 22, 46, 82, 110, 3, 99, 75, 36, 38, 119, 131, 51, 115, 78, 84, 33, 163, 11, 2, 188, 161, 34, 89, 50, 8, 90, 109, 136, 77, 103, 67, 41, 149, 176, 134, 189, 159, 184, 153, 53, 129, 63, 160, 139, 150, 169, 148, 127, 25, 175, 142, 98, 56, 144, 102, 94, 101, 85, 132, 76, 5, 177, 0, 128, 45, 162, 92, 62, 133, 30, 17, 9, 61, 70, 154, 4, 146, 24, 135, 104, 13, 185, 79, 138, 31, 112, 1, 49, 113, 106, 100, 65, 10, 83, 73, 26, 58, 114, 66, 126, 117, 96, 186, 14, 40, 164, 158, 118, 29, 121, 151, 168, 183, 179, 16, 105, 125, 190, 116, 165, 80, 64, 170, 140, 171, 173, 97, 60, 43, 123, 71, 182, 167, 95, 145, 141, 187, 166, 87, 143, 15, 74, 111, 157, 32, 172, 18, 57, 35, 191, 27, 47, 21, 6, 19, 155, 42, 120, 180, 37, 28, 91, 108, 7.

FIG. 153 is a diagram illustrating Example 34 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 153, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

139, 112, 159, 99, 87, 70, 175, 161, 51, 56, 174, 143, 12, 36, 77, 60, 155, 167, 160, 73, 127, 82, 123, 145, 8, 76, 164, 178, 144, 86, 7, 124, 27, 187, 130, 162, 191, 182, 16, 106, 141, 38, 72, 179, 111, 29, 59, 183, 66, 52, 43, 121, 20, 11, 190, 92, 55, 166, 94, 138, 1, 122, 171, 119, 109, 58, 23, 31, 163, 53, 13, 188, 100, 158, 156, 136, 34, 118, 185, 10, 25, 126, 104, 30, 83, 47, 146, 63, 134, 39, 21, 44, 151, 28, 22, 79, 110, 71, 90, 2, 103, 42, 35, 5, 57, 4, 0, 107, 37, 54, 18, 128, 148, 129, 26, 75, 120, 19, 116, 117, 147, 114, 48, 96, 61, 46, 88, 67, 135, 65, 180, 9, 74, 176, 6, 149, 49, 50, 125, 64, 169, 168, 157, 153, 24, 108, 89, 98, 33, 132, 93, 40, 154, 62, 142, 41, 69, 105, 189, 115, 152, 45, 133, 3, 95, 17, 186, 184, 85, 165, 32, 173, 113, 172, 78, 181, 150, 170, 102, 97, 140, 81, 91, 15, 137, 101, 80, 68, 14, 177, 131, 84.

FIG. 154 is a diagram illustrating Example 35 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 154, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

21, 20, 172, 86, 178, 25, 104, 133, 17, 106, 191, 68, 80, 190, 129, 29, 125, 108, 147, 23, 94, 167, 27, 61, 12, 166, 131, 120, 159, 28, 7, 62, 134, 59, 78, 0, 121, 149, 6, 5, 143, 171, 153, 161, 186, 35, 92, 113, 55, 163, 16, 54, 93, 79, 37, 44, 75, 182, 127, 148, 179, 95, 169, 141, 38, 168, 128, 56, 31, 57, 175, 140, 164, 24, 177, 88, 51, 112, 49, 185, 170, 87, 32, 60, 65, 77, 89, 3, 18, 116, 184, 45, 109, 53, 160, 9, 100, 8, 111, 69, 189, 36, 173, 33, 72, 144, 183, 115, 137, 98, 90, 142, 30, 154, 180, 122, 155, 130, 83, 138, 14, 41, 150, 132, 70, 152, 117, 11, 4, 124, 15, 42, 181, 58, 10, 22, 145, 99, 126, 107, 66, 174, 39, 13, 97, 63, 123, 84, 85, 67, 76, 158, 71, 46, 118, 81, 162, 146, 135, 2, 73, 50, 114, 82, 103, 188, 74, 101, 157, 151, 91, 119, 102, 48, 1, 40, 43, 64, 156, 34, 110, 52, 96, 136, 139, 165, 19, 176, 187, 47, 26, 105.

FIG. 155 is a diagram illustrating Example 36 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 155, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

160, 7, 29, 39, 110, 189, 140, 143, 163, 130, 173, 71, 191, 106, 60, 62, 149, 135, 9, 147, 124, 152, 55, 116, 85, 112, 14, 20, 79, 103, 156, 167, 19, 45, 73, 26, 159, 44, 86, 76, 56, 12, 109, 117, 128, 67, 150, 151, 31, 27, 133, 17, 120, 153, 108, 180, 52, 187, 98, 63, 176, 186, 179, 113, 161, 32, 24, 111, 41, 95, 38, 10, 154, 97, 141, 2, 127, 40, 105, 34, 11, 185, 155, 61, 114, 74, 158, 162, 5, 177, 43, 51, 148, 137, 28, 181, 171, 13, 104, 42, 168, 93, 172, 144, 80, 123, 89, 81, 68, 75, 78, 121, 53, 65, 122, 142, 157, 107, 136, 66, 90, 23, 8, 1, 77, 54, 125, 174, 35, 88, 82, 134, 101, 131, 33, 50, 87, 36, 15, 47, 83, 18, 6, 21, 30, 94, 72, 145, 138, 184, 69, 84, 58, 49, 16, 48, 70, 183, 3, 92, 25, 115, 0, 182, 139, 91, 146, 102, 96, 100, 119, 129, 178, 46, 37, 57, 118, 126, 59, 165, 170, 190, 188, 175, 166, 99, 4, 22, 132, 164, 64, 169.

FIG. 156 is a diagram illustrating Example 37 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 156, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

167, 97, 86, 166, 11, 57, 187, 169, 104, 102, 108, 63, 12, 181, 1, 71, 134, 152, 45, 144, 124, 22, 0, 51, 100, 150, 179, 54, 66, 79, 25, 172, 59, 48, 23, 55, 64, 185, 164, 123, 56, 80, 153, 9, 177, 176, 81, 17, 14, 43, 76, 27, 175, 60, 133, 91, 61, 41, 111, 163, 72, 95, 84, 67, 129, 52, 88, 121, 7, 49, 168, 154, 74, 138, 142, 158, 132, 127, 40, 139, 20, 44, 6, 128, 75, 114, 119, 2, 8, 157, 98, 118, 89, 46, 160, 190, 5, 165, 28, 68, 189, 161, 112, 173, 148, 183, 33, 131, 105, 186, 156, 70, 117, 170, 174, 36, 19, 135, 125, 122, 50, 113, 141, 37, 38, 31, 94, 149, 78, 32, 178, 34, 107, 13, 182, 146, 93, 10, 106, 109, 4, 77, 87, 3, 184, 83, 30, 180, 96, 15, 155, 110, 145, 191, 151, 101, 65, 99, 115, 140, 26, 147, 42, 136, 137, 18, 53, 116, 171, 16, 21, 92, 162, 130, 85, 69, 47, 35, 82, 120, 24, 73, 39, 58, 62, 126, 29, 90, 143, 159, 188, 103.

FIG. 157 is a diagram illustrating Example 38 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 157, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

74, 151, 79, 49, 174, 180, 133, 106, 116, 16, 163, 62, 164, 45, 187, 128, 176, 2, 126, 136, 63, 28, 118, 173, 19, 46, 93, 121, 162, 88, 0, 147, 131, 54, 117, 138, 69, 182, 68, 143, 78, 15, 7, 59, 109, 32, 10, 179, 165, 90, 73, 71, 171, 135, 123, 125, 31, 22, 70, 185, 155, 60, 120, 113, 41, 154, 177, 85, 64, 55, 26, 129, 84, 38, 166, 44, 30, 183, 189, 191, 124, 77, 80, 98, 190, 167, 140, 52, 153, 43, 25, 188, 103, 152, 137, 76, 149, 34, 172, 122, 40, 168, 141, 96, 142, 58, 110, 65, 9, 36, 42, 50, 184, 105, 156, 127, 8, 61, 146, 169, 181, 5, 87, 150, 91, 17, 18, 24, 112, 81, 170, 95, 29, 100, 130, 48, 159, 72, 75, 160, 27, 108, 148, 66, 144, 97, 57, 115, 114, 1, 132, 4, 21, 92, 11, 107, 175, 67, 145, 14, 186, 20, 51, 39, 3, 86, 89, 47, 53, 102, 82, 139, 23, 104, 157, 99, 158, 12, 161, 35, 178, 37, 134, 83, 94, 101, 111, 119, 6, 33, 13, 56.

FIG. 158 is a diagram illustrating Example 39 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 158, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

20, 118, 185, 106, 82, 53, 41, 40, 121, 180, 45, 10, 145, 175, 191, 160, 177, 172, 13, 29, 133, 42, 89, 51, 141, 99, 7, 134, 52, 48, 169, 162, 124, 25, 165, 128, 95, 148, 98, 171, 14, 75, 59, 26, 76, 47, 34, 122, 69, 131, 105, 60, 132, 63, 81, 109, 43, 189, 19, 186, 79, 62, 85, 54, 16, 46, 27, 44, 139, 113, 11, 102, 130, 184, 119, 1, 152, 146, 37, 178, 61, 150, 32, 163, 92, 166, 142, 67, 140, 157, 188, 18, 87, 149, 65, 183, 161, 5, 31, 71, 173, 73, 15, 138, 156, 28, 66, 170, 179, 135, 86, 39, 104, 17, 154, 174, 56, 153, 0, 97, 9, 72, 23, 167, 190, 80, 3, 38, 120, 4, 24, 159, 12, 103, 22, 125, 83, 50, 6, 77, 168, 74, 93, 49, 57, 147, 2, 155, 181, 96, 114, 107, 110, 30, 117, 127, 101, 94, 129, 35, 58, 70, 126, 182, 151, 111, 91, 64, 88, 144, 137, 143, 176, 84, 136, 8, 112, 123, 164, 115, 78, 36, 90, 100, 55, 108, 21, 158, 68, 33, 116, 187.

FIG. 159 is a diagram illustrating Example 40 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 159, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

42, 43, 190, 119, 183, 103, 51, 28, 171, 20, 18, 25, 85, 22, 157, 99, 174, 5, 53, 62, 150, 128, 38, 153, 37, 148, 39, 24, 118, 102, 184, 49, 111, 48, 87, 76, 81, 40, 55, 82, 70, 105, 66, 115, 14, 86, 88, 135, 168, 139, 56, 80, 93, 95, 165, 13, 4, 100, 29, 104, 11, 72, 116, 83, 112, 67, 186, 169, 8, 57, 44, 17, 164, 31, 96, 84, 2, 125, 59, 3, 6, 173, 149, 78, 27, 160, 156, 187, 34, 129, 154, 79, 52, 117, 110, 0, 7, 113, 137, 26, 47, 12, 178, 46, 136, 97, 15, 188, 101, 58, 35, 71, 32, 16, 109, 163, 134, 75, 68, 98, 132, 90, 124, 189, 121, 123, 170, 158, 159, 77, 108, 63, 180, 36, 74, 127, 21, 146, 147, 54, 155, 10, 144, 130, 60, 1, 141, 23, 177, 133, 50, 126, 167, 151, 161, 191, 91, 114, 162, 30, 181, 182, 9, 94, 69, 176, 65, 142, 152, 175, 73, 140, 41, 179, 172, 145, 64, 19, 138, 131, 166, 33, 107, 185, 106, 122, 120, 92, 45, 143, 61, 89.

FIG. 160 is a diagram illustrating Example 41 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 160, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

111, 33, 21, 133, 18, 30, 73, 139, 125, 35, 77, 105, 122, 91, 41, 86, 11, 8, 55, 71, 151, 107, 45, 12, 168, 51, 50, 59, 7, 132, 144, 16, 190, 31, 108, 89, 124, 110, 94, 67, 159, 46, 140, 87, 54, 142, 185, 85, 84, 120, 178, 101, 180, 20, 174, 47, 28, 145, 70, 24, 131, 4, 83, 56, 79, 37, 27, 109, 92, 52, 96, 177, 141, 188, 155, 38, 156, 169, 136, 81, 137, 112, 95, 93, 106, 149, 138, 15, 39, 170, 146, 103, 184, 43, 5, 9, 189, 34, 19, 63, 90, 36, 23, 78, 100, 75, 162, 42, 161, 119, 64, 65, 152, 62, 173, 104, 88, 118, 48, 44, 40, 60, 102, 61, 74, 99, 53, 10, 6, 172, 186, 163, 134, 14, 148, 3, 26, 1, 157, 150, 25, 123, 115, 116, 57, 175, 127, 82, 117, 114, 160, 164, 153, 176, 76, 13, 181, 68, 128, 0, 183, 49, 22, 166, 17, 191, 135, 165, 72, 158, 130, 154, 167, 66, 2, 147, 69, 58, 98, 97, 143, 32, 29, 179, 113, 80, 182, 129, 126, 171, 121, 187.

FIG. 161 is a diagram illustrating Example 42 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 161, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

148, 32, 94, 31, 146, 15, 41, 7, 79, 58, 52, 167, 154, 4, 161, 38, 64, 127, 131, 78, 34, 125, 171, 173, 133, 122, 50, 95, 129, 57, 71, 37, 137, 69, 82, 107, 26, 10, 140, 156, 47, 178, 163, 117, 139, 174, 143, 138, 111, 11, 166, 43, 141, 114, 45, 39, 177, 103, 96, 123, 63, 23, 18, 20, 187, 27, 66, 130, 65, 142, 5, 135, 113, 90, 121, 54, 190, 134, 153, 147, 92, 157, 3, 97, 102, 106, 172, 91, 46, 89, 56, 184, 115, 99, 62, 93, 100, 88, 152, 109, 124, 182, 70, 74, 159, 165, 60, 183, 185, 164, 175, 108, 176, 2, 118, 72, 151, 0, 51, 33, 28, 80, 14, 128, 179, 84, 77, 42, 55, 160, 119, 110, 86, 22, 101, 13, 170, 36, 104, 189, 191, 169, 112, 12, 29, 30, 162, 136, 24, 68, 9, 81, 120, 145, 180, 144, 73, 21, 44, 1, 16, 67, 19, 158, 188, 181, 61, 35, 8, 53, 168, 150, 105, 59, 87, 6, 126, 75, 85, 17, 83, 98, 48, 132, 40, 76, 49, 25, 149, 186, 155, 116.

FIG. 162 is a diagram illustrating Example 43 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 162, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

161, 38, 41, 138, 20, 24, 14, 35, 32, 179, 68, 97, 94, 142, 43, 53, 22, 28, 44, 81, 148, 187, 169, 89, 115, 144, 75, 40, 31, 152, 30, 124, 80, 135, 160, 8, 129, 147, 60, 112, 171, 0, 133, 100, 156, 180, 77, 110, 151, 69, 95, 25, 117, 127, 154, 64, 146, 143, 29, 168, 177, 183, 126, 10, 26, 3, 50, 92, 164, 163, 11, 109, 21, 37, 84, 122, 49, 71, 52, 15, 88, 149, 86, 61, 90, 155, 162, 9, 153, 67, 119, 189, 82, 131, 190, 4, 46, 118, 47, 178, 59, 150, 186, 123, 18, 79, 57, 120, 70, 62, 137, 23, 185, 167, 175, 16, 134, 73, 139, 166, 55, 165, 116, 76, 99, 182, 78, 93, 141, 33, 176, 101, 130, 58, 12, 17, 132, 45, 102, 7, 19, 145, 54, 91, 113, 36, 27, 114, 174, 39, 83, 140, 191, 74, 56, 87, 48, 158, 121, 159, 136, 63, 181, 34, 173, 103, 42, 125, 104, 107, 96, 65, 1, 13, 157, 184, 170, 105, 188, 108, 6, 2, 98, 72, 5, 66, 128, 106, 172, 111, 85, 51.

FIG. 163 is a diagram illustrating Example 44 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 163, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

57, 73, 173, 63, 179, 186, 148, 181, 160, 163, 4, 109, 137, 99, 118, 15, 5, 115, 44, 153, 185, 40, 12, 169, 2, 37, 188, 97, 65, 67, 117, 90, 66, 135, 154, 159, 146, 86, 61, 182, 59, 83, 91, 175, 58, 138, 93, 43, 98, 22, 152, 96, 45, 120, 180, 10, 116, 170, 162, 68, 3, 13, 41, 131, 21, 172, 55, 24, 1, 79, 106, 189, 52, 184, 112, 53, 136, 166, 29, 62, 107, 128, 71, 111, 187, 161, 101, 49, 155, 28, 94, 70, 48, 0, 33, 157, 151, 25, 89, 88, 114, 134, 75, 87, 142, 6, 27, 64, 69, 19, 150, 38, 35, 130, 127, 76, 102, 123, 158, 129, 133, 110, 141, 95, 7, 126, 85, 108, 174, 190, 165, 156, 171, 54, 17, 121, 103, 14, 36, 105, 82, 8, 178, 51, 23, 84, 167, 30, 100, 42, 72, 149, 92, 77, 104, 183, 39, 125, 80, 143, 144, 56, 119, 16, 132, 139, 191, 50, 164, 122, 46, 140, 31, 176, 60, 26, 32, 11, 177, 124, 74, 145, 20, 34, 18, 81, 168, 9, 78, 113, 147, 47.

FIG. 164 is a diagram illustrating Example 45 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 164, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

89, 123, 13, 47, 178, 159, 1, 190, 53, 12, 57, 109, 115, 19, 36, 143, 82, 96, 163, 66, 154, 173, 49, 65, 131, 2, 78, 15, 155, 90, 38, 130, 63, 188, 138, 184, 166, 102, 139, 28, 50, 186, 17, 20, 112, 41, 11, 8, 59, 79, 45, 162, 146, 40, 43, 129, 119, 18, 157, 37, 126, 124, 110, 191, 85, 165, 60, 142, 135, 74, 187, 179, 141, 164, 34, 69, 26, 33, 113, 120, 95, 169, 30, 0, 175, 70, 91, 104, 140, 25, 132, 23, 105, 158, 171, 6, 121, 56, 22, 127, 54, 68, 107, 133, 84, 81, 150, 99, 73, 185, 67, 29, 151, 87, 10, 167, 148, 72, 147, 5, 31, 125, 145, 4, 52, 44, 134, 83, 46, 75, 152, 62, 7, 86, 172, 180, 111, 61, 9, 58, 14, 116, 92, 170, 93, 77, 88, 42, 21, 106, 97, 144, 182, 108, 55, 94, 122, 114, 153, 64, 24, 80, 117, 3, 177, 149, 76, 128, 136, 39, 181, 160, 103, 174, 156, 27, 183, 16, 137, 101, 161, 176, 35, 118, 98, 168, 48, 100, 71, 189, 32, 51.

FIG. 165 is a diagram illustrating Example 46 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 165, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

116, 157, 105, 191, 110, 149, 0, 186, 88, 165, 141, 179, 160, 121, 35, 170, 97, 7, 181, 31, 130, 123, 184, 34, 101, 167, 68, 135, 18, 91, 159, 81, 53, 36, 164, 139, 61, 162, 79, 4, 176, 127, 42, 148, 147, 150, 55, 109, 132, 124, 9, 66, 14, 128, 134, 27, 29, 59, 153, 22, 120, 13, 187, 112, 69, 163, 11, 70, 58, 15, 25, 102, 188, 182, 156, 20, 17, 10, 32, 76, 5, 28, 46, 166, 140, 143, 65, 63, 107, 119, 87, 145, 62, 108, 189, 114, 71, 78, 122, 93, 37, 12, 137, 118, 56, 67, 98, 113, 173, 169, 39, 51, 177, 1, 84, 40, 158, 2, 144, 73, 43, 82, 92, 16, 133, 129, 99, 86, 57, 47, 183, 171, 131, 33, 26, 168, 155, 178, 175, 64, 52, 100, 142, 90, 8, 106, 45, 19, 24, 80, 146, 136, 125, 95, 172, 104, 154, 138, 6, 85, 94, 74, 151, 44, 174, 115, 185, 89, 23, 190, 111, 72, 180, 54, 77, 75, 117, 126, 49, 103, 48, 60, 83, 3, 21, 50, 161, 30, 96, 152, 41, 38.

FIG. 166 is a diagram illustrating Example 47 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 166, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

115, 167, 98, 128, 174, 73, 109, 79, 40, 6, 190, 113, 158, 56, 183, 61, 134, 13, 32, 133, 173, 1, 76, 151, 147, 70, 155, 77, 51, 150, 146, 12, 186, 33, 74, 171, 53, 11, 17, 68, 136, 9, 181, 91, 125, 161, 42, 124, 72, 96, 101, 81, 84, 107, 63, 55, 65, 5, 163, 157, 135, 18, 130, 120, 87, 85, 47, 187, 3, 46, 49, 112, 159, 188, 169, 127, 78, 25, 83, 45, 143, 182, 59, 36, 19, 110, 39, 43, 35, 15, 90, 180, 82, 145, 48, 34, 144, 178, 177, 86, 27, 103, 94, 62, 170, 57, 154, 166, 54, 164, 20, 185, 29, 2, 16, 60, 37, 75, 10, 162, 116, 92, 71, 106, 105, 175, 44, 108, 50, 26, 7, 176, 38, 99, 4, 122, 52, 66, 0, 140, 184, 24, 80, 97, 23, 114, 30, 126, 148, 64, 119, 165, 137, 123, 95, 111, 160, 8, 153, 149, 172, 121, 129, 28, 104, 156, 100, 189, 14, 138, 88, 118, 139, 93, 191, 31, 131, 179, 152, 89, 22, 41, 168, 117, 21, 69, 132, 102, 58, 67, 142, 141.

FIG. 167 is a diagram illustrating Example 48 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 167, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

31, 178, 143, 125, 159, 168, 34, 127, 158, 157, 21, 124, 153, 162, 59, 156, 165, 40, 108, 43, 98, 119, 33, 13, 175, 166, 117, 25, 63, 111, 74, 1, 38, 169, 131, 100, 164, 0, 171, 101, 151, 113, 20, 185, 17, 86, 146, 11, 12, 19, 145, 85, 3, 80, 133, 93, 10, 72, 152, 172, 140, 45, 115, 79, 161, 39, 99, 5, 37, 110, 155, 170, 123, 70, 52, 81, 65, 160, 132, 103, 9, 88, 15, 130, 71, 129, 177, 128, 121, 150, 36, 35, 163, 83, 142, 105, 48, 64, 82, 46, 148, 138, 147, 149, 27, 56, 47, 50, 42, 54, 182, 23, 97, 89, 167, 141, 75, 32, 118, 44, 96, 66, 73, 190, 181, 191, 92, 53, 87, 176, 102, 144, 28, 134, 77, 184, 189, 67, 187, 174, 49, 94, 68, 18, 186, 26, 120, 62, 136, 24, 4, 16, 61, 179, 106, 95, 135, 41, 173, 154, 78, 2, 22, 139, 76, 58, 90, 137, 114, 126, 51, 84, 14, 91, 183, 180, 112, 122, 30, 29, 69, 107, 116, 55, 8, 104, 6, 60, 57, 7, 109, 188.

FIG. 168 is a diagram illustrating Example 49 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 168, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

36, 20, 126, 165, 181, 59, 90, 186, 191, 120, 182, 170, 171, 137, 62, 84, 146, 106, 64, 129, 56, 136, 57, 108, 190, 74, 70, 10, 68, 139, 35, 104, 63, 16, 19, 66, 1, 15, 61, 97, 172, 72, 26, 141, 80, 151, 138, 156, 46, 82, 95, 142, 77, 76, 17, 102, 92, 60, 148, 99, 140, 2, 78, 145, 29, 174, 32, 103, 3, 133, 163, 23, 150, 155, 44, 185, 65, 134, 184, 11, 38, 119, 117, 167, 79, 5, 130, 94, 33, 157, 154, 109, 30, 31, 160, 96, 49, 178, 110, 128, 166, 7, 162, 48, 34, 55, 22, 143, 149, 121, 89, 114, 176, 107, 67, 73, 51, 53, 132, 83, 158, 69, 153, 180, 188, 101, 37, 179, 111, 71, 147, 189, 124, 43, 86, 98, 91, 45, 135, 168, 183, 42, 27, 81, 152, 164, 58, 100, 25, 4, 13, 144, 112, 122, 159, 187, 52, 85, 50, 9, 87, 127, 169, 173, 14, 93, 116, 175, 177, 24, 40, 0, 28, 12, 161, 105, 41, 75, 123, 39, 125, 18, 54, 6, 131, 118, 115, 88, 8, 113, 21, 47.

FIG. 169 is a diagram illustrating Example 50 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 169, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

12, 183, 40, 66, 35, 155, 137, 58, 108, 93, 47, 78, 56, 122, 51, 114, 10, 164, 148, 190, 53, 76, 75, 11, 46, 2, 174, 146, 119, 170, 98, 22, 116, 28, 67, 63, 59, 154, 94, 105, 187, 9, 97, 166, 19, 125, 189, 185, 178, 115, 123, 150, 60, 77, 86, 69, 26, 145, 143, 134, 124, 111, 162, 141, 80, 34, 138, 130, 45, 33, 127, 37, 91, 84, 102, 13, 16, 172, 61, 182, 57, 55, 101, 142, 117, 87, 131, 188, 191, 113, 39, 54, 74, 72, 29, 48, 161, 139, 151, 180, 1, 160, 103, 173, 15, 52, 186, 133, 71, 132, 31, 135, 70, 81, 24, 112, 6, 175, 96, 3, 79, 156, 109, 8, 153, 90, 177, 49, 99, 128, 21, 7, 158, 89, 92, 126, 32, 121, 100, 88, 163, 136, 20, 83, 17, 42, 95, 129, 118, 43, 157, 50, 5, 179, 140, 147, 62, 38, 176, 149, 159, 44, 106, 152, 65, 14, 168, 184, 0, 107, 167, 36, 73, 110, 165, 120, 104, 23, 25, 82, 27, 41, 181, 169, 85, 144, 4, 18, 171, 30, 68, 64.

FIG. 170 is a diagram illustrating Example 51 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern in FIG. 170, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

140, 166, 22, 87, 107, 121, 66, 80, 85, 109, 45, 13, 144, 63, 0, 52, 131, 122, 135, 173, 105, 98, 117, 168, 8, 123, 157, 93, 129, 37, 119, 143, 40, 59, 162, 21, 79, 102, 34, 36, 32, 41, 177, 48, 83, 94, 191, 78, 101, 155, 160, 189, 77, 57, 11, 148, 124, 65, 187, 110, 100, 114, 67, 150, 82, 156, 43, 5, 1, 126, 46, 167, 149, 72, 31, 161, 23, 113, 137, 132, 35, 76, 26, 61, 141, 15, 4, 25, 17, 182, 92, 29, 27, 73, 170, 53, 64, 127, 112, 171, 56, 106, 186, 183, 95, 165, 10, 103, 74, 84, 116, 20, 185, 6, 133, 147, 75, 62, 14, 142, 44, 181, 146, 164, 128, 9, 60, 50, 91, 88, 97, 145, 28, 7, 118, 99, 115, 39, 125, 136, 180, 179, 96, 175, 3, 47, 158, 172, 154, 138, 176, 33, 81, 134, 120, 174, 151, 49, 30, 108, 68, 38, 153, 2, 69, 111, 54, 130, 71, 24, 58, 178, 19, 42, 51, 190, 89, 16, 90, 169, 70, 18, 86, 184, 12, 188, 163, 55, 139, 104, 152, 159.

FIG. 171 is a diagram illustrating Example 52 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 171, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

128, 120, 91, 121, 189, 30, 127, 35, 76, 26, 144, 45, 178, 93, 14, 31, 123, 155, 19, 28, 152, 174, 177, 168, 56, 169, 95, 7, 96, 133, 136, 146, 172, 187, 90, 44, 98, 150, 40, 20, 104, 191, 37, 61, 42, 43, 27, 159, 163, 100, 164, 151, 111, 102, 165, 132, 138, 180, 22, 70, 184, 62, 167, 134, 60, 160, 175, 157, 153, 77, 87, 185, 116, 115, 176, 78, 5, 39, 88, 33, 126, 13, 71, 188, 171, 135, 21, 16, 143, 51, 99, 182, 85, 129, 162, 66, 0, 55, 73, 117, 75, 181, 179, 53, 170, 1, 125, 69, 80, 83, 57, 38, 103, 109, 137, 63, 74, 9, 15, 118, 67, 2, 113, 124, 114, 6, 154, 141, 50, 149, 4, 46, 8, 130, 94, 34, 23, 54, 145, 81, 58, 82, 139, 156, 108, 140, 166, 36, 183, 110, 101, 161, 84, 119, 92, 3, 142, 186, 158, 173, 147, 49, 10, 32, 65, 89, 86, 131, 18, 47, 107, 79, 72, 25, 68, 122, 29, 11, 41, 190, 59, 52, 97, 148, 12, 24, 105, 17, 106, 48, 64, 112.

FIG. 172 is a diagram illustrating Example 53 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 172, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

36, 180, 61, 100, 163, 168, 14, 24, 105, 104, 131, 56, 40, 73, 165, 157, 126, 47, 160, 181, 166, 161, 1, 81, 58, 182, 189, 177, 85, 17, 13, 46, 171, 149, 91, 79, 109, 133, 164, 125, 52, 77, 118, 186, 107, 150, 135, 33, 130, 87, 167, 158, 23, 83, 152, 114, 68, 12, 132, 178, 106, 184, 176, 72, 31, 53, 21, 110, 76, 146, 4, 18, 113, 65, 34, 179, 111, 185, 84, 144, 27, 39, 151, 50, 69, 30, 169, 175, 9, 42, 54, 43, 90, 22, 139, 129, 170, 115, 45, 140, 67, 25, 155, 82, 102, 29, 188, 108, 15, 80, 128, 48, 0, 64, 141, 93, 191, 190, 174, 32, 35, 119, 159, 41, 55, 162, 49, 59, 88, 156, 123, 136, 28, 60, 26, 16, 89, 147, 92, 98, 38, 20, 173, 71, 44, 94, 5, 7, 99, 75, 122, 120, 66, 121, 112, 62, 8, 137, 142, 103, 116, 117, 37, 63, 70, 86, 10, 74, 95, 11, 134, 154, 51, 101, 127, 183, 57, 97, 78, 148, 6, 172, 3, 138, 145, 153, 143, 19, 2, 96, 187, 124.

FIG. 173 is a diagram illustrating Example 54 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 173, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

92, 83, 138, 67, 27, 88, 13, 26, 73, 16, 187, 18, 76, 28, 79, 130, 91, 58, 140, 38, 6, 43, 17, 168, 141, 96, 70, 147, 112, 164, 97, 161, 139, 65, 78, 95, 146, 3, 32, 158, 24, 0, 94, 120, 176, 128, 59, 81, 21, 102, 190, 8, 114, 113, 29, 45, 103, 56, 54, 173, 177, 12, 174, 108, 169, 148, 123, 129, 150, 77, 157, 184, 61, 127, 121, 156, 104, 111, 68, 160, 107, 117, 124, 84, 35, 10, 90, 106, 144, 66, 64, 15, 46, 125, 44, 37, 20, 135, 53, 71, 152, 183, 162, 50, 167, 11, 142, 149, 131, 191, 166, 31, 185, 134, 19, 178, 52, 188, 2, 75, 110, 145, 41, 159, 136, 100, 9, 62, 60, 34, 116, 23, 42, 105, 40, 118, 186, 4, 5, 182, 170, 87, 1, 22, 55, 126, 63, 14, 25, 153, 98, 49, 33, 69, 179, 171, 93, 36, 133, 57, 151, 82, 72, 163, 86, 47, 119, 48, 99, 30, 189, 115, 165, 101, 80, 175, 132, 89, 39, 181, 85, 51, 154, 137, 7, 180, 155, 74, 109, 122, 172, 143.

FIG. 174 is a diagram illustrating Example 55 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 174, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

52, 117, 42, 131, 45, 120, 44, 63, 91, 0, 33, 176, 95, 36, 134, 170, 148, 32, 130, 20, 124, 51, 152, 96, 92, 90, 184, 103, 53, 14, 110, 80, 107, 145, 181, 137, 61, 149, 114, 126, 136, 161, 58, 162, 88, 8, 171, 178, 174, 94, 118, 19, 35, 1, 191, 115, 23, 10, 150, 67, 46, 56, 172, 129, 109, 98, 89, 68, 101, 121, 78, 182, 12, 173, 128, 77, 168, 156, 186, 165, 39, 187, 5, 158, 104, 2, 49, 154, 59, 82, 65, 30, 127, 17, 113, 164, 179, 34, 69, 189, 123, 147, 183, 21, 163, 143, 57, 100, 28, 185, 25, 140, 13, 66, 141, 62, 47, 54, 169, 106, 38, 86, 116, 151, 41, 4, 75, 108, 85, 153, 72, 125, 22, 135, 50, 70, 74, 11, 76, 138, 132, 55, 167, 40, 144, 31, 142, 37, 29, 99, 83, 26, 119, 64, 27, 9, 15, 97, 73, 133, 79, 190, 111, 43, 48, 102, 7, 139, 84, 24, 112, 177, 16, 180, 175, 81, 3, 60, 18, 188, 93, 105, 157, 87, 166, 159, 155, 122, 146, 6, 160, 71.

FIG. 175 is a diagram illustrating Example 56 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 175, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

60, 117, 182, 104, 53, 26, 11, 121, 71, 32, 179, 34, 38, 145, 166, 65, 137, 7, 124, 58, 90, 29, 144, 116, 91, 88, 98, 161, 83, 177, 85, 154, 146, 178, 123, 76, 75, 3, 64, 151, 99, 118, 57, 106, 16, 61, 162, 19, 12, 94, 39, 93, 92, 73, 82, 138, 108, 139, 130, 163, 152, 159, 168, 189, 102, 134, 101, 66, 4, 171, 170, 188, 107, 23, 180, 35, 175, 18, 89, 181, 17, 97, 62, 56, 52, 128, 40, 25, 191, 74, 95, 143, 5, 8, 1, 132, 133, 135, 184, 33, 37, 45, 127, 122, 136, 190, 158, 72, 77, 114, 46, 55, 105, 78, 183, 103, 22, 20, 24, 155, 86, 63, 79, 164, 13, 174, 2, 14, 47, 126, 84, 165, 59, 142, 87, 153, 112, 43, 156, 50, 6, 0, 81, 51, 21, 9, 148, 111, 147, 48, 31, 36, 129, 167, 150, 70, 42, 15, 110, 119, 109, 125, 80, 27, 131, 49, 140, 187, 96, 120, 100, 141, 160, 186, 185, 68, 69, 28, 176, 169, 44, 173, 149, 54, 115, 113, 67, 10, 157, 41, 30, 172.

FIG. 176 is a diagram illustrating Example 57 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 176, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

7, 156, 171, 76, 165, 68, 5, 72, 86, 57, 42, 98, 162, 130, 88, 31, 63, 170, 92, 100, 145, 146, 117, 62, 123, 55, 22, 138, 75, 99, 177, 83, 135, 190, 79, 84, 182, 140, 136, 0, 108, 77, 8, 154, 73, 37, 147, 14, 10, 128, 111, 168, 38, 159, 125, 32, 120, 132, 148, 27, 69, 96, 127, 103, 34, 110, 161, 41, 18, 35, 142, 116, 28, 121, 91, 112, 51, 178, 139, 95, 155, 20, 78, 33, 133, 29, 9, 54, 24, 176, 122, 3, 102, 56, 181, 175, 174, 81, 166, 30, 26, 43, 113, 137, 150, 89, 179, 70, 11, 2, 118, 183, 13, 50, 46, 12, 49, 40, 172, 17, 47, 65, 16, 74, 141, 129, 101, 48, 87, 187, 167, 134, 158, 15, 44, 53, 93, 152, 23, 126, 52, 97, 189, 36, 115, 169, 64, 25, 58, 82, 1, 45, 39, 191, 144, 173, 6, 60, 85, 149, 163, 21, 90, 4, 80, 105, 164, 180, 61, 114, 188, 151, 185, 94, 124, 104, 106, 119, 107, 160, 67, 71, 19, 131, 186, 153, 157, 66, 143, 184, 109, 59.

FIG. 177 is a diagram illustrating Example 58 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 177, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

134, 124, 102, 133, 161, 34, 18, 17, 119, 172, 43, 25, 130, 84, 46, 167, 23, 100, 31, 121, 30, 15, 99, 127, 62, 20, 143, 103, 139, 171, 13, 42, 1, 26, 76, 159, 27, 82, 48, 146, 22, 156, 188, 69, 86, 177, 129, 160, 33, 67, 176, 148, 168, 158, 169, 0, 155, 118, 154, 110, 96, 191, 4, 36, 39, 56, 112, 14, 145, 182, 3, 88, 126, 91, 105, 174, 128, 157, 125, 74, 116, 61, 52, 187, 117, 98, 73, 95, 92, 181, 111, 65, 63, 152, 163, 147, 66, 178, 87, 179, 64, 93, 144, 83, 140, 8, 78, 2, 131, 115, 123, 47, 94, 186, 28, 68, 21, 135, 37, 151, 11, 104, 77, 81, 35, 71, 162, 97, 41, 58, 190, 101, 153, 85, 166, 7, 173, 44, 29, 10, 49, 54, 150, 32, 50, 51, 45, 183, 107, 113, 137, 80, 79, 175, 142, 141, 138, 40, 122, 75, 120, 53, 59, 60, 184, 5, 38, 6, 164, 189, 24, 16, 72, 19, 109, 106, 114, 108, 185, 165, 149, 9, 57, 170, 12, 90, 180, 89, 132, 136, 55, 70.

FIG. 178 is a diagram illustrating Example 59 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 178, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

18, 161, 152, 30, 91, 138, 83, 88, 127, 54, 33, 46, 125, 120, 122, 169, 51, 150, 100, 52, 95, 186, 149, 81, 11, 53, 164, 130, 19, 176, 93, 107, 29, 86, 124, 65, 75, 71, 74, 68, 44, 82, 59, 104, 118, 103, 131, 101, 8, 96, 97, 119, 166, 77, 50, 34, 158, 21, 184, 24, 165, 171, 142, 36, 181, 45, 90, 175, 99, 13, 37, 10, 140, 3, 69, 16, 133, 172, 173, 27, 132, 79, 76, 111, 123, 7, 94, 70, 116, 174, 15, 156, 187, 110, 84, 185, 14, 72, 159, 143, 78, 135, 17, 12, 139, 67, 58, 151, 177, 73, 154, 145, 179, 25, 108, 148, 137, 85, 147, 61, 20, 89, 155, 183, 134, 128, 191, 26, 121, 126, 0, 141, 112, 62, 114, 48, 182, 146, 115, 64, 113, 189, 31, 1, 39, 168, 2, 43, 163, 188, 35, 129, 153, 66, 23, 40, 6, 5, 98, 56, 9, 63, 180, 157, 167, 162, 60, 42, 49, 28, 22, 80, 87, 92, 160, 55, 136, 170, 106, 117, 178, 32, 38, 105, 102, 41, 57, 109, 144, 47, 190, 4.

FIG. 179 is a diagram illustrating Example 60 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 179, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

172, 48, 104, 60, 184, 162, 86, 185, 11, 132, 155, 50, 146, 178, 5, 28, 133, 169, 106, 90, 174, 95, 42, 10, 78, 177, 21, 112, 54, 153, 136, 12, 115, 108, 92, 152, 180, 151, 13, 62, 25, 51, 191, 84, 167, 139, 96, 111, 130, 150, 7, 143, 144, 117, 124, 27, 38, 72, 6, 128, 36, 39, 26, 156, 32, 127, 181, 122, 52, 131, 68, 140, 173, 182, 154, 190, 137, 61, 2, 138, 43, 110, 29, 116, 176, 30, 57, 189, 14, 4, 65, 80, 33, 75, 135, 20, 103, 98, 56, 179, 129, 105, 113, 71, 160, 85, 55, 0, 166, 59, 183, 142, 19, 22, 63, 125, 165, 88, 87, 93, 168, 77, 45, 69, 175, 100, 145, 31, 91, 141, 114, 157, 119, 16, 1, 34, 15, 147, 46, 188, 70, 74, 109, 126, 18, 64, 89, 134, 9, 161, 158, 44, 3, 47, 148, 187, 81, 164, 121, 35, 23, 24, 159, 82, 40, 94, 67, 163, 170, 58, 97, 8, 83, 53, 118, 149, 73, 107, 123, 79, 41, 99, 186, 101, 49, 120, 66, 76, 17, 171, 102, 37.

FIG. 180 is a diagram illustrating Example 61 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 180, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

16, 133, 14, 114, 145, 191, 53, 80, 166, 68, 21, 184, 73, 165, 147, 89, 180, 55, 135, 94, 189, 78, 103, 115, 72, 24, 105, 188, 84, 148, 85, 32, 1, 131, 34, 134, 41, 167, 81, 54, 142, 141, 75, 155, 122, 140, 13, 17, 8, 23, 61, 49, 51, 74, 181, 162, 143, 42, 71, 123, 161, 177, 110, 149, 126, 0, 63, 178, 35, 175, 186, 52, 43, 139, 112, 10, 40, 150, 182, 164, 64, 83, 174, 38, 47, 30, 2, 116, 25, 128, 160, 144, 99, 5, 187, 176, 82, 60, 18, 185, 104, 169, 39, 183, 137, 22, 109, 96, 151, 46, 33, 29, 65, 132, 95, 31, 136, 159, 170, 168, 67, 79, 93, 111, 90, 97, 113, 92, 76, 58, 127, 26, 27, 156, 3, 6, 28, 77, 125, 173, 98, 138, 172, 86, 45, 118, 171, 62, 179, 100, 19, 163, 50, 57, 56, 36, 102, 121, 117, 154, 119, 66, 20, 91, 130, 69, 44, 70, 153, 152, 158, 88, 108, 12, 59, 4, 11, 120, 87, 101, 37, 129, 146, 9, 106, 48, 7, 15, 124, 190, 107, 157.

FIG. 181 is a diagram illustrating Example 62 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 181, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

97, 121, 122, 73, 108, 167, 75, 156, 64, 49, 29, 18, 110, 171, 8, 27, 54, 41, 164, 15, 129, 157, 130, 111, 112, 120, 152, 12, 13, 101, 31, 69, 180, 143, 78, 125, 79, 172, 40, 116, 58, 71, 126, 55, 35, 191, 185, 159, 44, 86, 3, 80, 88, 145, 98, 144, 0, 62, 38, 150, 166, 114, 139, 60, 149, 10, 72, 155, 181, 26, 85, 128, 19, 25, 4, 170, 94, 175, 136, 117, 135, 102, 21, 89, 140, 138, 100, 33, 142, 74, 133, 56, 124, 17, 77, 65, 119, 59, 182, 105, 99, 158, 24, 96, 70, 83, 23, 81, 132, 7, 141, 61, 57, 82, 115, 162, 186, 103, 43, 148, 47, 176, 113, 151, 50, 184, 165, 109, 189, 90, 32, 20, 46, 127, 153, 161, 106, 11, 67, 36, 9, 28, 174, 160, 16, 93, 95, 6, 131, 66, 39, 14, 91, 163, 68, 48, 123, 137, 52, 5, 183, 76, 179, 22, 34, 147, 107, 168, 146, 42, 173, 53, 190, 104, 51, 118, 45, 30, 178, 134, 169, 37, 187, 177, 1, 2, 154, 87, 63, 92, 188, 84.

FIG. 182 is a diagram illustrating Example 63 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 182, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

47, 85, 118, 136, 166, 98, 72, 163, 63, 116, 162, 169, 114, 124, 144, 110, 46, 152, 104, 88, 99, 106, 181, 109, 3, 10, 172, 107, 33, 100, 191, 75, 157, 79, 52, 128, 6, 12, 139, 30, 68, 111, 83, 5, 119, 1, 97, 56, 38, 117, 78, 80, 155, 141, 185, 20, 161, 123, 28, 180, 77, 50, 29, 64, 41, 121, 53, 36, 48, 127, 44, 22, 35, 165, 59, 147, 187, 153, 89, 154, 18, 55, 90, 69, 19, 148, 129, 188, 24, 8, 102, 151, 11, 74, 105, 81, 92, 70, 101, 7, 132, 120, 112, 145, 57, 96, 42, 45, 91, 71, 149, 164, 51, 130, 95, 140, 178, 9, 135, 34, 175, 21, 32, 25, 67, 17, 61, 58, 134, 43, 122, 2, 16, 183, 54, 86, 4, 39, 60, 184, 171, 94, 179, 13, 115, 49, 143, 158, 168, 159, 87, 73, 156, 15, 93, 125, 126, 131, 40, 66, 138, 76, 173, 65, 27, 170, 186, 182, 103, 108, 82, 37, 174, 167, 142, 26, 160, 84, 62, 190, 176, 31, 150, 189, 113, 137, 14, 23, 0, 146, 177, 133.

FIG. 183 is a diagram illustrating Example 64 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 183, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

97, 39, 99, 33, 10, 6, 189, 179, 130, 172, 76, 185, 131, 40, 176, 159, 8, 17, 167, 116, 16, 160, 5, 174, 27, 115, 43, 41, 136, 175, 153, 144, 106, 29, 105, 84, 67, 35, 152, 191, 72, 56, 83, 168, 12, 184, 65, 146, 104, 80, 98, 79, 51, 26, 64, 137, 181, 165, 52, 129, 186, 48, 128, 154, 58, 141, 77, 187, 94, 109, 81, 119, 82, 38, 18, 188, 143, 170, 147, 2, 162, 95, 21, 11, 74, 151, 19, 59, 1, 138, 145, 7, 177, 30, 42, 44, 28, 20, 91, 14, 4, 70, 110, 31, 37, 61, 55, 85, 15, 183, 171, 96, 103, 101, 112, 161, 54, 178, 78, 87, 126, 57, 180, 88, 92, 113, 73, 90, 117, 93, 89, 122, 62, 25, 158, 148, 118, 45, 123, 60, 107, 173, 114, 166, 120, 13, 23, 139, 86, 135, 164, 47, 124, 149, 150, 46, 157, 100, 142, 0, 71, 50, 49, 36, 9, 127, 156, 75, 34, 163, 125, 190, 182, 155, 66, 69, 140, 32, 169, 132, 53, 68, 102, 63, 133, 111, 22, 134, 108, 3, 24, 121.

FIG. 184 is a diagram illustrating Example 65 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 184, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

35, 75, 166, 145, 143, 184, 62, 96, 54, 63, 157, 103, 32, 43, 126, 187, 144, 91, 78, 44, 39, 109, 185, 102, 10, 68, 29, 42, 149, 83, 133, 94, 130, 27, 171, 19, 51, 165, 148, 28, 36, 33, 173, 136, 87, 82, 100, 49, 120, 152, 161, 162, 147, 71, 137, 57, 8, 53, 132, 151, 163, 123, 47, 92, 90, 60, 99, 79, 59, 108, 115, 72, 0, 12, 140, 160, 61, 180, 74, 37, 86, 117, 191, 101, 52, 15, 80, 156, 127, 81, 131, 141, 142, 31, 95, 4, 73, 64, 16, 18, 146, 70, 181, 7, 89, 124, 77, 67, 116, 21, 34, 41, 105, 113, 97, 2, 6, 55, 17, 65, 38, 48, 158, 159, 179, 5, 30, 183, 170, 135, 125, 20, 106, 186, 182, 188, 114, 1, 14, 3, 134, 178, 189, 167, 40, 119, 22, 190, 58, 23, 155, 138, 98, 84, 11, 110, 88, 46, 177, 175, 25, 150, 118, 121, 129, 168, 13, 128, 104, 69, 112, 169, 9, 45, 174, 93, 26, 56, 76, 50, 154, 139, 66, 85, 153, 107, 111, 172, 176, 164, 24, 122.

FIG. 185 is a diagram illustrating Example 66 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 185, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

138, 38, 106, 76, 172, 27, 150, 95, 44, 187, 64, 18, 28, 98, 180, 101, 149, 146, 126, 26, 93, 178, 186, 70, 104, 131, 19, 45, 102, 122, 152, 66, 63, 173, 9, 55, 25, 1, 154, 85, 5, 51, 43, 82, 86, 151, 148, 48, 190, 179, 62, 60, 94, 174, 142, 39, 169, 170, 47, 125, 33, 128, 162, 2, 129, 57, 79, 118, 114, 69, 78, 167, 11, 136, 99, 155, 90, 21, 119, 10, 52, 91, 115, 185, 6, 110, 88, 96, 181, 143, 0, 160, 124, 130, 183, 71, 121, 182, 68, 191, 3, 32, 40, 189, 41, 156, 35, 159, 58, 89, 29, 67, 17, 109, 30, 111, 12, 46, 65, 177, 53, 77, 74, 56, 184, 15, 141, 135, 54, 163, 14, 145, 139, 134, 59, 147, 87, 107, 7, 61, 36, 113, 103, 188, 24, 165, 137, 22, 42, 49, 83, 73, 50, 161, 20, 166, 127, 157, 108, 171, 37, 72, 176, 112, 123, 144, 34, 175, 168, 117, 80, 81, 8, 31, 133, 92, 164, 132, 97, 158, 84, 100, 140, 16, 105, 23, 75, 13, 153, 116, 4, 120.

FIG. 186 is a diagram illustrating Example 67 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 186, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

37, 136, 161, 62, 163, 129, 160, 73, 76, 66, 34, 162, 122, 5, 87, 94, 50, 105, 132, 32, 121, 47, 74, 189, 110, 45, 75, 175, 17, 29, 108, 191, 1, 153, 20, 113, 61, 42, 51, 2, 165, 124, 43, 186, 40, 86, 168, 180, 155, 16, 93, 26, 166, 119, 159, 56, 12, 44, 46, 143, 49, 25, 176, 158, 92, 147, 54, 172, 182, 64, 157, 112, 38, 39, 11, 6, 127, 48, 151, 82, 4, 36, 183, 88, 126, 117, 111, 188, 138, 65, 70, 170, 133, 137, 146, 128, 114, 148, 141, 125, 10, 41, 116, 33, 99, 81, 187, 130, 131, 107, 60, 90, 173, 13, 71, 15, 106, 3, 149, 154, 181, 174, 190, 27, 177, 18, 21, 22, 83, 91, 150, 14, 96, 53, 0, 145, 67, 68, 144, 184, 59, 23, 118, 115, 135, 55, 134, 102, 8, 169, 85, 156, 97, 63, 104, 95, 52, 98, 139, 24, 78, 179, 19, 28, 69, 58, 109, 57, 164, 31, 84, 140, 103, 77, 123, 171, 72, 79, 152, 35, 80, 7, 185, 167, 9, 100, 142, 89, 30, 120, 178, 101.

FIG. 187 is a diagram illustrating Example 68 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 187, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

148, 189, 3, 121, 80, 135, 7, 96, 46, 109, 190, 111, 118, 23, 5, 149, 19, 140, 106, 36, 161, 71, 6, 176, 160, 76, 8, 168, 171, 173, 40, 37, 25, 50, 164, 108, 139, 31, 127, 142, 163, 177, 24, 20, 157, 83, 116, 42, 73, 69, 88, 184, 147, 136, 187, 49, 45, 35, 170, 62, 63, 181, 117, 123, 122, 72, 55, 53, 133, 159, 94, 175, 179, 158, 97, 93, 13, 130, 144, 81, 68, 2, 64, 155, 119, 43, 143, 1, 112, 18, 146, 172, 132, 191, 134, 61, 138, 9, 178, 103, 15, 47, 154, 17, 152, 153, 107, 115, 39, 166, 33, 104, 56, 52, 60, 131, 141, 78, 186, 162, 54, 0, 85, 12, 86, 77, 126, 34, 180, 10, 87, 38, 4, 26, 79, 27, 98, 66, 75, 67, 110, 101, 128, 16, 22, 28, 151, 21, 99, 74, 11, 100, 65, 58, 150, 145, 14, 59, 102, 51, 48, 113, 92, 167, 188, 174, 156, 114, 82, 125, 124, 70, 137, 90, 30, 44, 57, 105, 95, 165, 29, 89, 41, 169, 120, 91, 32, 183, 129, 182, 185, 84.

FIG. 188 is a diagram illustrating Example 69 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 188, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

67, 20, 9, 75, 143, 94, 144, 122, 56, 88, 180, 72, 102, 100, 113, 157, 170, 59, 128, 162, 26, 38, 61, 156, 115, 117, 190, 77, 22, 74, 119, 12, 8, 179, 182, 85, 188, 191, 154, 41, 58, 142, 186, 107, 73, 189, 15, 130, 127, 160, 55, 19, 45, 137, 124, 133, 146, 43, 60, 183, 153, 177, 123, 181, 95, 49, 140, 4, 51, 3, 21, 164, 83, 187, 148, 11, 168, 149, 92, 65, 30, 90, 23, 116, 57, 161, 125, 175, 129, 126, 97, 14, 96, 66, 37, 178, 64, 173, 184, 80, 101, 34, 81, 131, 76, 147, 47, 135, 111, 121, 44, 68, 98, 48, 120, 40, 87, 176, 104, 106, 28, 163, 52, 1, 152, 79, 42, 139, 16, 2, 71, 7, 109, 114, 112, 54, 62, 169, 35, 150, 171, 110, 50, 108, 105, 69, 118, 84, 39, 132, 63, 31, 18, 134, 103, 185, 6, 145, 24, 70, 36, 29, 5, 93, 99, 33, 82, 89, 167, 174, 27, 165, 91, 138, 155, 32, 159, 141, 136, 151, 25, 158, 86, 17, 13, 172, 53, 10, 46, 166, 0, 78.

FIG. 189 is a diagram illustrating Example 70 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 189, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

84, 126, 45, 76, 121, 91, 52, 162, 79, 187, 134, 108, 47, 16, 72, 119, 43, 107, 98, 135, 147, 110, 0, 60, 4, 61, 117, 24, 167, 65, 40, 55, 73, 112, 85, 35, 156, 95, 137, 171, 9, 11, 54, 131, 138, 157, 152, 111, 183, 161, 41, 69, 21, 94, 113, 8, 153, 39, 57, 143, 86, 12, 188, 184, 15, 30, 118, 136, 64, 169, 148, 22, 6, 68, 168, 78, 105, 101, 190, 3, 59, 124, 170, 62, 87, 46, 28, 29, 186, 2, 25, 177, 140, 53, 154, 37, 18, 189, 93, 114, 33, 1, 158, 122, 103, 5, 104, 80, 166, 34, 106, 51, 10, 180, 139, 125, 178, 100, 13, 70, 142, 185, 159, 50, 66, 102, 150, 127, 160, 92, 81, 173, 115, 144, 145, 128, 74, 88, 20, 116, 179, 96, 17, 155, 175, 75, 165, 7, 191, 149, 44, 23, 99, 48, 163, 42, 63, 164, 90, 120, 27, 31, 14, 19, 32, 174, 26, 67, 89, 97, 56, 146, 82, 133, 129, 109, 71, 58, 130, 182, 123, 176, 49, 36, 181, 38, 141, 151, 83, 77, 172, 132.

FIG. 190 is a diagram illustrating Example 71 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 190, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

30, 127, 60, 115, 80, 50, 150, 39, 176, 171, 47, 104, 70, 33, 56, 3, 10, 26, 19, 149, 153, 141, 98, 46, 64, 71, 130, 107, 94, 16, 164, 169, 57, 168, 126, 157, 133, 12, 154, 135, 35, 53, 40, 183, 28, 1, 160, 67, 163, 134, 181, 59, 99, 186, 86, 36, 178, 152, 48, 117, 44, 14, 66, 172, 17, 31, 182, 166, 187, 55, 62, 143, 69, 77, 9, 113, 158, 91, 189, 84, 151, 74, 45, 97, 122, 114, 75, 41, 162, 90, 110, 106, 116, 131, 129, 188, 92, 11, 147, 108, 20, 159, 146, 51, 29, 109, 89, 6, 96, 155, 43, 111, 138, 85, 119, 5, 22, 105, 170, 4, 15, 148, 145, 63, 0, 156, 81, 68, 13, 137, 79, 103, 2, 179, 38, 180, 132, 123, 144, 167, 140, 174, 49, 37, 82, 128, 101, 21, 124, 177, 121, 8, 23, 136, 42, 27, 139, 72, 185, 18, 65, 161, 7, 125, 88, 34, 73, 184, 52, 190, 120, 102, 100, 87, 95, 118, 83, 112, 175, 78, 58, 24, 165, 54, 61, 25, 191, 76, 142, 93, 173, 32.

FIG. 191 is a diagram illustrating Example 72 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 191, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

166, 161, 43, 77, 177, 54, 162, 185, 127, 62, 6, 64, 30, 12, 27, 89, 130, 116, 190, 28, 38, 135, 149, 164, 48, 173, 175, 71, 132, 68, 5, 111, 158, 24, 59, 26, 145, 118, 51, 37, 178, 69, 189, 163, 133, 98, 53, 29, 169, 188, 17, 180, 155, 73, 45, 22, 107, 104, 76, 143, 70, 88, 99, 124, 126, 34, 80, 10, 168, 66, 72, 123, 63, 140, 176, 49, 65, 50, 52, 122, 4, 181, 121, 57, 18, 101, 42, 179, 100, 157, 165, 106, 156, 95, 170, 174, 117, 109, 102, 186, 148, 3, 134, 96, 67, 150, 151, 153, 11, 83, 1, 105, 25, 144, 8, 108, 84, 78, 97, 141, 60, 16, 112, 7, 82, 93, 46, 137, 35, 103, 61, 113, 129, 20, 119, 92, 31, 154, 115, 56, 44, 90, 14, 131, 160, 2, 36, 21, 23, 110, 152, 187, 0, 184, 41, 183, 120, 146, 47, 114, 32, 81, 75, 39, 91, 136, 167, 172, 58, 147, 125, 86, 138, 94, 33, 79, 159, 87, 55, 171, 85, 182, 191, 9, 19, 74, 13, 142, 40, 139, 15, 128.

FIG. 192 is a diagram illustrating Example 73 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 192, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

191, 38, 101, 9, 62, 79, 127, 18, 51, 6, 95, 114, 35, 123, 31, 99, 133, 81, 136, 106, 5, 130, 159, 124, 146, 41, 110, 150, 185, 8, 158, 178, 119, 171, 121, 129, 164, 168, 111, 52, 177, 190, 85, 179, 142, 174, 46, 61, 176, 23, 163, 49, 28, 86, 2, 143, 120, 166, 13, 87, 27, 39, 115, 131, 92, 117, 187, 56, 11, 180, 118, 30, 149, 60, 71, 44, 103, 140, 48, 162, 125, 122, 126, 29, 153, 77, 72, 4, 7, 165, 25, 89, 26, 68, 20, 12, 141, 37, 139, 15, 36, 82, 21, 137, 80, 3, 57, 128, 42, 43, 47, 93, 147, 70, 50, 170, 54, 96, 17, 152, 24, 172, 10, 22, 45, 169, 83, 69, 134, 78, 64, 183, 76, 189, 184, 112, 109, 33, 88, 32, 105, 175, 94, 53, 1, 90, 66, 100, 19, 108, 104, 113, 58, 40, 144, 97, 138, 154, 148, 157, 67, 145, 102, 132, 173, 84, 167, 0, 98, 182, 156, 63, 135, 14, 181, 73, 75, 65, 161, 116, 186, 55, 34, 151, 91, 160, 107, 16, 188, 74, 155, 59.

FIG. 193 is a diagram illustrating Example 74 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 193, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

100, 152, 16, 39, 26, 58, 60, 6, 126, 7, 59, 75, 62, 47, 27, 113, 41, 115, 169, 30, 95, 189, 138, 136, 70, 140, 149, 187, 177, 141, 125, 171, 178, 134, 15, 154, 131, 183, 46, 35, 44, 11, 51, 170, 112, 20, 161, 159, 101, 52, 181, 71, 28, 128, 3, 167, 156, 123, 18, 139, 102, 13, 19, 37, 90, 105, 92, 135, 185, 121, 50, 158, 29, 104, 155, 12, 184, 93, 166, 14, 133, 146, 24, 191, 188, 116, 109, 89, 65, 45, 25, 21, 1, 76, 151, 180, 33, 124, 91, 107, 119, 5, 132, 118, 111, 96, 143, 150, 173, 108, 2, 122, 22, 148, 130, 142, 147, 67, 97, 103, 36, 63, 40, 117, 55, 68, 137, 144, 94, 83, 56, 79, 175, 0, 182, 114, 85, 86, 9, 10, 74, 106, 17, 190, 4, 34, 84, 98, 38, 88, 64, 78, 145, 77, 163, 42, 120, 69, 164, 48, 23, 129, 160, 81, 127, 82, 53, 72, 179, 31, 66, 32, 168, 110, 73, 186, 157, 172, 49, 165, 176, 80, 61, 174, 153, 162, 54, 99, 57, 87, 8, 43.

FIG. 194 is a diagram illustrating Example 75 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 194, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

21, 5, 2, 24, 12, 28, 52, 118, 129, 3, 122, 149, 105, 16, 136, 99, 133, 171, 84, 79, 59, 62, 155, 78, 134, 20, 1, 51, 22, 161, 173, 46, 172, 162, 55, 148, 70, 57, 121, 86, 131, 114, 31, 72, 104, 120, 164, 127, 83, 179, 187, 7, 108, 40, 73, 144, 48, 68, 60, 190, 135, 61, 116, 106, 19, 35, 143, 180, 102, 76, 182, 117, 93, 191, 165, 23, 80, 146, 153, 42, 53, 139, 124, 64, 167, 96, 138, 132, 158, 90, 110, 82, 39, 175, 170, 66, 145, 94, 119, 130, 98, 63, 87, 32, 160, 34, 151, 77, 95, 109, 56, 113, 147, 50, 38, 15, 156, 11, 169, 185, 183, 92, 186, 107, 10, 101, 33, 4, 150, 41, 81, 89, 166, 0, 30, 54, 168, 26, 140, 74, 100, 9, 111, 126, 43, 112, 25, 88, 44, 189, 37, 178, 141, 49, 13, 29, 8, 69, 154, 45, 97, 47, 36, 75, 137, 6, 115, 188, 85, 174, 17, 142, 18, 91, 163, 157, 177, 103, 125, 71, 14, 181, 65, 184, 176, 159, 128, 152, 58, 27, 123, 67.

FIG. 195 is a diagram illustrating Example 76 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 195, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

113, 23, 166, 150, 133, 130, 38, 18, 71, 115, 111, 44, 135, 11, 98, 96, 67, 114, 112, 87, 146, 119, 28, 86, 120, 49, 175, 14, 30, 144, 53, 165, 162, 128, 108, 39, 116, 158, 62, 110, 83, 93, 118, 80, 88, 173, 157, 102, 177, 132, 174, 59, 106, 34, 64, 22, 4, 29, 97, 155, 109, 9, 107, 92, 36, 24, 161, 50, 21, 137, 17, 43, 58, 124, 31, 37, 172, 100, 178, 129, 79, 160, 167, 32, 181, 154, 7, 183, 90, 54, 68, 191, 156, 104, 147, 10, 65, 81, 134, 169, 142, 57, 171, 78, 48, 47, 5, 40, 46, 51, 151, 77, 1, 72, 164, 152, 70, 141, 2, 89, 13, 182, 85, 52, 41, 66, 75, 63, 185, 148, 179, 138, 61, 73, 180, 189, 76, 84, 8, 27, 184, 105, 42, 69, 153, 188, 19, 131, 121, 26, 159, 45, 16, 186, 25, 176, 82, 103, 163, 99, 101, 122, 187, 20, 136, 126, 168, 145, 6, 91, 55, 117, 35, 56, 143, 140, 190, 125, 127, 74, 95, 94, 12, 149, 33, 0, 139, 3, 123, 170, 15, 60.

FIG. 196 is a diagram illustrating Example 77 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 196, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

131, 148, 141, 17, 53, 138, 45, 97, 112, 111, 77, 184, 129, 135, 27, 122, 2, 123, 156, 128, 80, 116, 40, 89, 84, 41, 105, 42, 39, 187, 145, 18, 54, 44, 183, 57, 136, 13, 65, 162, 51, 178, 59, 104, 163, 70, 87, 152, 94, 126, 23, 169, 9, 179, 177, 139, 130, 38, 35, 20, 86, 180, 48, 108, 47, 133, 167, 75, 168, 25, 67, 185, 91, 165, 157, 158, 110, 127, 82, 58, 50, 64, 76, 31, 159, 8, 79, 78, 146, 71, 69, 3, 36, 155, 160, 21, 29, 49, 28, 150, 81, 154, 149, 182, 24, 30, 72, 109, 173, 33, 113, 43, 55, 189, 132, 176, 120, 172, 166, 143, 90, 125, 7, 5, 66, 12, 98, 83, 10, 62, 11, 175, 85, 0, 63, 181, 188, 74, 171, 117, 106, 61, 153, 174, 147, 93, 190, 34, 142, 100, 6, 1, 140, 191, 161, 19, 151, 14, 73, 99, 121, 119, 92, 95, 115, 118, 186, 60, 144, 22, 32, 52, 164, 15, 88, 46, 114, 101, 124, 26, 96, 4, 107, 103, 16, 37, 102, 56, 170, 68, 134, 137.

FIG. 197 is a diagram illustrating Example 78 of a GW pattern for an LDPC code with a code length N of 69120 bits.

According to the GW pattern of FIG. 197, the arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group

93, 61, 37, 170, 63, 60, 135, 5, 158, 47, 65, 179, 76, 182, 72, 20, 104, 7, 181, 11, 117, 152, 184, 172, 143, 92, 109, 177, 191, 119, 132, 1, 98, 10, 148, 35, 126, 9, 18, 70, 190, 38, 66, 54, 62, 122, 100, 3, 2, 189, 144, 153, 165, 14, 154, 44, 161, 113, 147, 12, 90, 167, 112, 34, 39, 139, 142, 41, 159, 149, 82, 131, 88, 106, 138, 105, 55, 163, 71, 168, 80, 96, 108, 40, 50, 25, 114, 79, 103, 141, 151, 69, 74, 110, 36, 24, 67, 145, 26, 8, 56, 180, 13, 17, 134, 28, 129, 185, 85, 121, 137, 136, 68, 86, 188, 0, 124, 120, 127, 32, 94, 83, 133, 97, 31, 58, 33, 57, 166, 162, 183, 186, 81, 111, 19, 107, 155, 42, 84, 6, 43, 130, 48, 123, 64, 78, 53, 173, 95, 75, 45, 174, 178, 160, 15, 187, 102, 23, 150, 156, 101, 99, 91, 157, 128, 175, 59, 125, 22, 46, 115, 164, 52, 16, 21, 30, 176, 146, 51, 116, 87, 140, 77, 73, 89, 169, 4, 171, 27, 49, 29, 118.

The first to 45 Examples of the GW pattern for the LDPC code with a code length N of 69120 bits can be applied to any combination of the LDPC code with a code length N of 69120 bits and an arbitrary encoding rate r, an arbitrary modulation scheme, and an arbitrary constellation.

However, for the group-wise interleaving, the error rate can be further improved for each combination by setting the GW pattern to be applied to a combination of the code length N of the LDPC code, the encoding rate r of the LDPC code, the modulation scheme, and the constellation.

The GW pattern of FIG. 120 is applied to, for example, a combination of the LDPC code (LDPC code with a code length N of 69120 and an encoding rate r of 2/16) with N=69120 and r=2/16 of FIG. 30 (corresponding to the check matrix initial value table), the QPSK, and the QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 121 is applied to, for example, a combination of the LDPC code with N=69120 and r=3/16 of FIGS. 31 and 32, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 122 is applied to, for example, a combination of the LDPC code with N=69120 and r=4/16 of FIG. 33, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 123 is applied to, for example, a combination of the LDPC code with N=69120 and r=5/16 of FIGS. 34 and 35, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 124 is applied to, for example, a combination of the LDPC code with N=69120 and r=6/16 of FIGS. 36 and 37, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 125 is applied to, for example, a combination of the LDPC code with N=69120 and r=7/16 of FIGS. 38 and 39, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 126 is applied to, for example, a combination of the LDPC code with N=69120 and r=8/16 of FIGS. 46 and 47, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 127 is applied to, for example, a combination of the LDPC code with N=69120 and r=9/16 of FIGS. 50 to 52, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 128 is applied to, for example, a combination of the LDPC code with N=69120 and r=10/16 of FIGS. 56 to 58, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 129 is applied to, for example, a combination of the LDPC code with N=69120 and r=11/16 of FIGS. 62 to 64, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 130 is applied to, for example, a combination of the LDPC code with N=69120 and r=12/16 of FIGS. 68 to 70, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 131 is applied to, for example, a combination of the LDPC code with N=69120 and r=13/16 of FIGS. 74 to 76, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 132 is applied to, for example, a combination of the LDPC code with N=69120 and r=14/6 of FIGS. 80 to 82, QPSK, and QPSK-UC of FIGS. 96 and 97, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 133 is applied to, for example, a combination of the LDPC code with N=69120 and r=3/16 of FIGS. 31 and 32 and 16QAM, and 16QAM-UC of FIGS. 98 and 99, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 134 is applied to, for example, a combination of the LDPC code with N=69120 and r=5/16 of FIGS. 34 and 35, 16QAM, and 16QAM-UC of FIGS. 98 and 99, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 135 is applied to, for example, a combination of the LDPC code with N=69120 and r=7/16 of FIGS. 38 and 39, 16QAM, and 16QAM-UC of FIGS. 98 and 99, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 136 is applied to, for example, a combination of the LDPC code with N=69120 and r=9/16 of FIGS. 50 to 52, 16QAM, and 16QAM-UC of FIGS. 98 and 99, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 137 is applied to, for example, a combination of the LDPC code with N=69120 and r=11/16 of FIGS. 62 to 64, 16QAM, and 16QAM-UC of FIGS. 98 and 99, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 138 is applied to, for example, a combination of the LDPC code with N=69120 and r=13/16 of FIGS. 74 to 76, 16QAM, and 16QAM-UC of FIGS. 98 and 99, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 139 is applied to, for example, a combination of the LDPC code with N=69120 and r=2/16 of FIG. 30, 64QAM, and 64QAM-UC of FIGS. 100 and 101, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 140 is applied to, for example, a combination of the LDPC code with N=69120 and r=4/16 of FIG. 33, 64QAM, and 64QAM-UC of FIGS. 100 and 101, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 141 is applied to, for example, a combination of the LDPC code with N=69120 and r=6/16 of FIGS. 36 and 37, 64QAM, and 64QAM-UC of FIGS. 100 and 101, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 142 is applied to, for example, a combination of the LDPC code with N=69120 and r=8/16 of FIGS. 46 and 47, 64QAM, and 64QAM-UC of FIGS. 100 and 101, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 143 is applied to, for example, a combination of the LDPC code with N=69120 and r=10/16 of FIGS. 56 to 58, 64QAM, and 64QAM-UC of FIGS. 100 and 101, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 144 is applied to, for example, a combination of the LDPC code with N=69120 and r=12/16 of FIGS. 68 to 70, 64QAM, and 64QAM-UC of FIGS. 100 and 101, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 145 is applied to, for example, a combination of the LDPC code with N=69120 and r=14/6 of FIGS. 80 to 82, 64QAM, and 64QAM-UC of FIGS. 100 and 101, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 146 is applied to, for example, a combination of the LDPC code with N=69120 and r=3/16 of FIGS. 31 and 32, 256QAM, and 256QAM-UC of FIGS. 102 and 103, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 147 is applied to, for example, a combination of the LDPC code with N=69120 and r=5/16 of FIGS. 34 and 35, 256QAM, and 256QAM-UC of FIGS. 102 and 103, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 148 is applied to, for example, a combination of the LDPC code with N=69120 and r=7/16 of FIGS. 38 and 39, 256QAM, and 256QAM-UC of FIGS. 102 and 103, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 149 is applied to, for example, a combination of the LDPC code with N=69120 and r=9/16 of FIGS. 50 to 52, 256QAM, and 256QAM-UC of FIGS. 102 and 103, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 150 is applied to, for example, a combination of the LDPC code with N=69120 and r=11/16 of FIGS. 62 to 64, 256QAM, and 256QAM-UC of FIGS. 102 and 103, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 151 is applied to, for example, a combination of the LDPC code with N=69120 and r=13/16 of FIGS. 74 to 76, 256QAM, and 256QAM-UC of FIGS. 102 and 103, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 152 is applied to, for example, a combination of the LDPC code with N=69120 and r=2/16 of FIG. 30, 1024QAM, and 1024QAM-UC of FIGS. 104 and 105, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 153 is applied to, for example, a combination of the LDPC code with N=69120 and r=4/16 of FIG. 33, 1024QAM, and 1024QAM-UC of FIGS. 104 and 105, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 154 is applied to, for example, a combination of the LDPC code with N=69120 and r=6/16 of FIGS. 36 and 37, 1024QAM, and 1024QAM-UC of FIGS. 104 and 105, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 155 is applied to, for example, a combination of the LDPC code with N=69120 and r=8/16 of FIGS. 46 and 47, 1024QAM, and 1024QAM-UC of FIGS. 104 and 105, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 156 is applied to, for example, a combination of the LDPC code with N=69120 and r=10/16 of FIGS. 56 to 58, 1024QAM, and 1024QAM-UC of FIGS. 104 and 105, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 157 is applied to, for example, a combination of the LDPC code with N=69120 and r=12/16 of FIGS. 68 to 70, 1024QAM, and 1024QAM-UC of FIGS. 104 and 105, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 158 is applied to, for example, a combination of the LDPC code with N=69120 and r=14/6 of FIGS. 80 to 82, 1024QAM, and 1024QAM-UC of FIGS. 104 and 105, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 159 is applied to, for example, a combination of the LDPC code with N=69120 and r=3/16 of FIGS. 31 and 32, 4096QAM, and 4096QAM-UC of FIGS. 106 and 107, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 160 is applied to, for example, a combination of the LDPC code with N=69120 and r=5/16 of FIGS. 34 and 35, 4096QAM, and 4096QAM-UC of FIGS. 106 and 107, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 161 is applied to, for example, a combination of the LDPC code with N=69120 and r=7/16 of FIGS. 38 and 39, 4096QAM, and 4096QAM-UC of FIGS. 106 and 107, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 162 is applied to, for example, a combination of the LDPC code with N=69120 and r=9/16 of FIGS. 50 to 52, 4096QAM, and 4096QAM-UC of FIGS. 106 and 107, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 163 is applied to, for example, a combination of the LDPC code with N=69120 and r=11/16 of FIGS. 62 to 64, 4096QAM, and 4096QAM-UC of FIGS. 106 and 107, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 164 is applied to, for example, a combination of the LDPC code with N=69120 and r=13/16 of FIGS. 74 to 76, 4096QAM, and 4096QAM-UC of FIGS. 106 and 107, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 165 is applied to, for example, a combination of the LDPC code with N=69120 and r=2/16 of FIG. 30, 16QAM, and 16QAM-2D-NUC of FIG. 108, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 166 is applied to, for example, a combination of the LDPC code with N=69120 and r=4/16 of FIG. 33, 16QAM, and 16QAM-2D-NUC of FIG. 108, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 167 is applied to, for example, a combination of the LDPC code with N=69120 and r=6/16 of FIGS. 36 and 37, 16QAM, and 16QAM-2D-NUC of FIG. 108, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 168 is applied to, for example, a combination of the LDPC code with N=69120 and r=8/16 of FIGS. 46 and 47, 16QAM, and 16QAM-2D-NUC of FIG. 108, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 169 is applied to, for example, a combination of the LDPC code with N=69120 and r=10/16 of FIGS. 56 to 58, 16QAM, and 16QAM-2D-NUC of FIG. 108, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 170 is applied to, for example, a combination of the LDPC code with N=69120 and r=12/16 of FIGS. 68 to 70, 16QAM, and 16QAM-2D-NUC of FIG. 108, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 171 is applied to, for example, a combination of the LDPC code with N=69120 and r=14/6 of FIGS. 80 to 82, 16QAM, and 16QAM-2D-NUC of FIG. 108, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 172 is applied to, for example, a combination of the LDPC code with N=69120 and r=3/16 of FIGS. 31 and 32, 64QAM, and 64QAM-2D-NUC of FIG. 109, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 173 is applied to, for example, a combination of the LDPC code with N=69120 and r=5/16 of FIGS. 34 and 35, 64QAM, and 64QAM-2D-NUC of FIG. 109, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 174 is applied to, for example, a combination of the LDPC code with N=69120 and r=7/16 of FIGS. 38 and 39, 64QAM, and 64QAM-2D-NUC of FIG. 109, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 175 is applied to, for example, a combination of the LDPC code with N=69120 and r=9/16 of FIGS. 50 to 52, 64QAM, and 64QAM-2D-NUC of FIG. 109, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 176 is applied to, for example, a combination of the LDPC code with N=69120 and r=11/16 of FIGS. 62 to 64, 64QAM, and 64QAM-2D-NUC of FIG. 109, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 177 is applied to, for example, a combination of the LDPC code with N=69120 and r=13/16 of FIGS. 74 to 76, 64QAM, and 64QAM-2D-NUC of FIG. 109, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 178 is applied to, for example, a combination of the LDPC code with N=69120 and r=2/16 of FIG. 30, 256QAM, and 256QAM-2D-NUC of FIGS. 110 and 111, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 179 is applied to, for example, a combination of the LDPC code with N=69120 and r=4/16 of FIG. 33, 256QAM, and 256QAM-2D-NUC of FIGS. 110 and 111, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 180 is applied to, for example, a combination of the LDPC code with N=69120 and r=6/16 of FIGS. 36 and 37, 256QAM, and 256QAM-2D-NUC of FIGS. 110 and 111, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 181 is applied to, for example, a combination of the LDPC code with N=69120 and r=8/16 of FIGS. 46 and 47, 256QAM, and 256QAM-2D-NUC of FIGS. 110 and 111, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 182 is applied to, for example, a combination of the LDPC code with N=69120 and r=10/16 of FIGS. 56 to 58, 256QAM, and 256QAM-2D-NUC of FIGS. 110 and 111, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 183 is applied to, for example, a combination of the LDPC code with N=69120 and r=12/16 of FIGS. 68 to 70, 256QAM, and 256QAM-2D-NUC of FIGS. 110 and 111, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 184 is applied to, for example, a combination of the LDPC code with N=69120 and r=14/16 of FIGS. 80 to 82, 256QAM, and 256QAM-2D-NUC of FIGS. 110 and 111, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 185 is applied to, for example, a combination of the LDPC code with N=69120 and r=3/16 of FIGS. 31 and 32, 1024QAM, and 1024QAM-1D-NUC of FIGS. 112, 113A and 1138, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 186 is applied to, for example, a combination of the LDPC code with N=69120 and r=5/16 of FIGS. 34 and 35, 1024QAM, and 1024QAM-1D-NUC of FIGS. 112, 113A and 113B, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 187 applied to, for example, a combination of the LDPC code with N=69120 and r=7/16 of FIGS. 38 and 39, 1024QAM, and 1024QAM-1D-NUC of FIGS. 112, 113A and 113B, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 188 is applied to, for example, a combination of the LDPC code with N=69120 and r=9/16 of FIGS. 50 to 52, 1024QAM, and 1024QAM-1D-NUC of FIGS. 112, 113A and 113B, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 189 is applied to, for example, a combination of the LDPC code with N=69120 and r=11/16 of FIGS. 62 to 64, 1024QAM, and 1024QAM-1D-NUC of FIGS. 112, 113A and 113B, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 190 is applied to, for example, a combination of the LDPC code with N=69120 and r=13/16 of FIGS. 74 to 76, 1024QAM, and 1024QAM-1D-NUC of FIGS. 112, 113A and 113B, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 191 is applied to, for example, a combination of the LDPC code with N=69120 and r=2/16 of FIG. 30, 4096QAM, and 4096QAM-1D-NUC of FIGS. 114 to 116, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 192 is applied to, for example, a combination of the LDPC code with N=69120 and r=4/16 of FIG. 33, 4096QAM, and 4096QAM-1D-NUC of FIGS. 114 to 116, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 193 is applied to, for example, a combination of the LDPC code with N=69120 and r=6/16 of FIGS. 36 and 37, 4096QAM, and 4096QAM-1D-NUC of FIGS. 114 to 116, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 194 is applied to, for example, a combination of the LDPC code with N=69120 and r=8/16 of FIGS. 46 and 47, 4096QAM, and 4096QAM-1D-NUC of FIGS. 114 to 116, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 195 is applied to, for example, a combination of the LDPC code with N=69120 and r=10/16 of FIGS. 56 to 58, 4096QAM, and 4096QAM-1D-NUC of FIGS. 114 to 116, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 196 is applied to, for example, a combination of the LDPC code with N=69120 and r=12/16 of FIGS. 68 to 70, 4096QAM, and 4096QAM-1D-NUC of FIGS. 114 to 116, so that a particularly good error rate can be achieved.

The GW pattern of FIG. 197 is applied to, for example, a combination of the LDPC code with N=69120 and r=14/6 of FIGS. 80 to 82, 4096QAM, and 4096QAM-1D-NUC of FIGS. 114 to 116, so that a particularly good error rate can be achieved.

<Configuration Example of Reception Device 12>

FIG. 198 is a block diagram illustrating a configuration example of the reception device 12 of FIG. 7.

An OFDM processing unit (OFDM operation) 151 receives an OFDM signal from the transmission device 11 (FIG. 7) and performs signal processing on the OFDM signal. Data obtained by the OFDM processing unit 151 performing signal processing is supplied to a frame management unit 152.

The frame management unit 152 processes (frames interprets) a frame configured with the data supplied from the OFDM processing unit 151 and supplies a signal of target data obtained as a result thereof and a signal of control data to frequency deinterleavers 161 and 153, respectively.

The frequency deinterleaver 153 performs frequency deinterleaving in units of a symbol on the data from the frame management unit 152 and supplies the data obtained as a result thereof to a demapper 154.

The demapper 154 performs demapping (decoding of the arrangement of signal points) and quadrature demodulation on the data (data on the constellation) from the frequency deinterleaver 153 on the basis of the arrangement (constellation) of the signal points determined by the quadrature modulation performed on the transmission device 11 side and supplies the data ((the likelihood of) the LDPC code) obtained as a result thereof to an LDPC decoder 155.

The LDPC decoder 155 performs LDPC decoding on the LDPC code from the demapper 154 and supplies the LDPC target data (herein, BCH code) obtained as a result thereof to a BCH decoder 156.

The BCH decoder 156 performs BCH decoding on the LDPC target data from the LDPC decoder 155 and outputs a control data (signaling) obtained as a result.

On the other hand, the frequency deinterleaver 161 performs frequency deinterleaving in units of a symbol on the data from the frame management unit 152 and supplies the data obtained as a result thereof to an SISO/MISO decoder 162.

The SISO/MISO decoder 162 performs space-time decoding on the data from the frequency deinterleaver 161 and supplies the data obtained as a result thereof to a time deinterleaver 163.

The time deinterleaver 163 performs time deinterleaving in units of a symbol on the data from the SISO/MISO decoder 162 and supplies the data obtained as a result thereof to a demapper 164.

The demapper 164 performs demapping (decoding of the arrangement of signal points) and quadrature demodulation on the data (data on the constellation) from the time deinterleaver 163 on the basis of the arrangement (constellation) of the signal points determined by the quadrature modulation performed on the transmission device 11 side and supplies the data obtained as a result thereof to a bit deinterleaver 165.

The bit deinterleaver 165 performs bit deinterleaving on the data from the demapper 164 and supplies (the likelihood of) the LDPC code that is the data after the bit deinterleaving to an LDPC decoder 166.

The LDPC decoder 166 performs LDPC decoding on the LDPC code from the bit deinterleaver 165 and supplies the LDPC target data (here, the BCH code) obtained as a result thereof to a BCH decoder 167.

The BCH decoder 167 performs BCH decoding on the LDPC target data from the LDPC decoder 155 and supplies the data obtained as a result thereof to a BB descrambler 168.

The BB descrambler 168 performs BB descrambling on the data from the BCH decoder 167 and supplies the data obtained a result thereof to a null deletion unit 169.

The null deletion unit 169 deletes the null inserted in the padder 112 of FIG. 8 from the data from the BB descrambler 168 and supplies the data obtained as a result thereof to a demultiplexer 170.

The demultiplexer 170 separates each of one or more streams (target data) multiplexed into the data from the null deletion unit 169, performs necessary processing, and outputs the data obtained as a result thereof as an output stream.

In addition, the reception device 12 can be configured without providing a portion of the blocks illustrated in FIG. 198. That is, for example, in a case where the transmission device 11 (FIG. 8) is configured without the time interleaver 118, the SISO/MISO encoder 119, the frequency interleaver 120, and the frequency interleaver 124, the reception device 12 can be configured without providing a time deinterleaver 163, an SISO/MISO decoder 162, a frequency deinterleaver 161, and a frequency deinterleaver 153 which are blocks corresponding to the time interleaver 118, the SISO/MISO encoder 119, the frequency interleaver 120, and the frequency interleaver 124 of the transmission device 11, respectively.

<Configuration Example of Bit Deinterleaver 165>

FIG. 199 is a block diagram illustrating a configuration example of the bit deinterleaver 165 of FIG. 198.

The bit deinterleaver 165 includes a block deinterleaver 54 and a group-wise deinterleaver 55, and performs (bit) deinterleaving of symbol bits of symbols that are data from the demapper 164 (FIG. 198).

That is, the block deinterleaver 54 performs block deinterleaving (reverse processing of block interleaving) corresponding to the block interleaving performed by the block interleaver 25 of FIG. 9 on the symbol bits of the symbols from the demapper 164, that is, block deinterleaving to return the position of (the likelihood of) the code bits of the LDPC code rearranged by the block interleaving to the original position and supplies the LDPC code obtained as a result thereof to the group-wise deinterleaver 55.

The group-wise deinterleaver 55 performs group-wise deinterleaving (a reverse process of the group-wise interleaving) corresponding to the group-wise interleaving performed by the group-wise interleaver 24 of FIG. 9 on the LDPC code from the block deinterleaver 54, that is, group-wise deinterleaving to return the code bits of the LDPC code rearranged in units of bit groups by the group-wise interleaving described with reference to, for example, FIG. 119 to the original arrangement by rearranging in units of bit groups.

Herein, in a case where the parity interleaving, the group-wise interleaving, and the block interleaving are performed on the LDPC code supplied from the demapper 164 to the bit deinterleaver 165, the bit deinterleaver 165 can perform all of the parity deinterleaving (a reverse process of the parity interleaving, that is, the parity deinterleaving to return the code bits of the LDPC code rearranged by the parity interleaving to the original arrangement) corresponding to the parity interleaving, the block deinterleaving corresponding to the block interleaving, and the group-wise deinterleaving corresponding to the group-wise interleaving.

However, in the bit deinterleaver 165 of FIG. 199, although the block deinterleaver 54 that performs the block deinterleaving corresponding to the block interleaving and the group-wise deinterleaver 55 that performs the group-wise deinterleaving corresponding to the group-wise interleaving are provided, a block that performs the parity deinterleaving corresponding to the parity interleaving is not provided, and the parity deinterleaving is not performed.

Therefore, an LDPC code on which the block deinterleaving and the group-wise deinterleaving are performed and the parity deinterleaving is not performed is supplied from the bit deinterleaver 165 (group-wise deinterleaver 55) to the LDPC decoder 166.

The LDPC decoder 166 performs the LDPC decoding on the LDPC code from the bit deinterleaver 165 by using the transformed check matrix obtained by performing at least the column permutation corresponding to the parity interleaving on the check matrix H of the type-B scheme used by the LDPC encoder 115 of FIG. 8 or the transformed check matrix (FIG. 29) obtained by performing the row permutation on the check matrix of the type-A scheme (FIG. 27) and outputs the data obtained as a result thereof as a result of the decoding of the LDPC target data.

FIG. 200 is a flowchart illustrating processing performed by the demapper 164, the bit deinterleaver 165, and the LDPC decoder 166 of FIG. 199.

In step S111, the demapper 164 performs demapping and quadrature demodulation on the data (data on the constellation mapped to the signal point) from the time deinterleaver 163 and supplies the data obtained as a result thereof to the bit deinterleaver 165, and the process proceeds to step S112.

In step S112, the bit deinterleaver 165 performs the deinterleaving (bit deinterleaving) on the data from the demapper 164, and the process proceeds to step S113.

That is, in step S112, in the bit deinterleaver 165, the block deinterleaver 54 performs the block deinterleaving on the data (symbols) from the demapper 164 and supplies the code bits of the LDPC code obtained as a result thereof to the group-wise deinterleaver 55.

The group-wise deinterleaver 55 performs the group-wise deinterleaving on the LDPC code from the block deinterleaver 54 and supplies (the likelihood of) the resulting LDPC code to the LDPC decoder 166.

In step S113, the LDPC decoder 166 performs LDPC decoding on the LDPC code from the group-wise deinterleaver 55 by using the check matrix H used in the LDPC encoding by the LDPC encoder 115 of FIG. 8, that is, by using, for example, the transformed check matrix obtained from the check matrix and outputs the data obtained as a result thereof to the BCH decoder 167 as a result of the decoding of the LDPC target data.

In addition, in FIG. 199, similarly to the case of FIG. 9, for the convenience of description, the block deinterleaver 54 for performing the block deinterleaving and the group-wise deinterleaver 55 for performing the group-wise deinterleaving are separately configured. However, the block deinterleaver 54 and the group-wise deinterleaver 55 can be integrally configured.

In addition, in a case where the group-wise interleaving is not performed in the transmission device 11, the reception device 12 can be configured without providing the group-wise deinterleaver 55 for performing the group-wise deinterleaving.

<LDPC Decoding>

The LDPC decoding performed by the LDPC decoder 166 of FIG. 198 will be further described.

The LDPC decoder 166 in FIG. 198, as described above, performs the LDPC decoding of the LDPC codes, on which the block deinterleaving and the group-wise deinterleaving from the group-wise deinterleaver 55 are performed and the parity deinterleaving is not performed, by using the transformed check matrix obtained by performing at least the column permutation corresponding to the parity interleaving on the check matrix H of the type-B scheme used for the LDPC encoding by the LDPC encoder 115 in FIG. 8 or the transformed check matrix (FIG. 29) obtained by performing the row permutation on the check matrix (FIG. 27) of the type-A scheme.

Herein, LDPC decoding that can refrain an operating frequency to a sufficiently feasible range while suppressing the circuit scale by performing the LDPC decoding by using a transformed check matrix, has been proposed previously (for example, refer to U.S. Pat. No. 4,224,777).

Therefore, first, the LDPC decoding using the transformed check matrix, which has been previously proposed, will be described with reference to FIGS. 201 to 204.

FIG. 201 is a diagram illustrating an example of a check matrix H of an LDPC code with a code length N of 90 and an encoding rate of 2/3.

Note that, in FIG. 201 (similar to FIGS. 202 and 203 described later), 0 is represented by a period (.).

In the check matrix H of FIG. 201, the parity matrix has a staircase structure.

FIG. 202 is a diagram illustrating a check matrix H′ obtained by performing the row permutation of Formula (11) and the column permutation of Formula (12) on the check matrix H of FIG. 201. Row Permutation: (6s+t+1)-th Row→(5t+s+1)-th Row  (11) Column Permutation: (6x+y+61)-th Column→(5y+x+61)-th Column  (12)

However, in Formulas (11) and (12), s, t, x, and y are integers in the ranges of 0≤s<5, 0≤t<6, 0≤x<5, and 0≤t<6, respectively.

According to the row permutation of Formula (11), permutation is performed such that the 1st, 7th, 13th, 19th and 25th rows of which the remainders of division by 6 are 1 become the 1st, 2nd, 3rd, 4th, and 5th rows, respectively, and the 2nd, 8th, 14th, 20th, and 26th rows of which the remainders of division by 6 are 2 become 6th, 7th, 8th, 9th, and 10th rows, respectively.

In addition, according to the column permutation of Formula (12), permutation is performed such that, for the 61st and subsequent columns (parity matrix), the 61st, 67th, 73rd, 79th, and 85th columns of which the remainders of division by 6 are 1 become the 61st, 62nd, 63rd, 64th, and 65th columns, respectively, and the 62nd, 68th, 74th, 80th, and 86th columns of which the remainders of division by 6 are 2 become the 66th, 67th, 68th, 69th, and 70, respectively.

Thus, the matrix obtained by performing row permutation and column permutation on the check matrix H of FIG. 201 is the check matrix H′ of FIG. 202.

Herein, the row permutation of the check matrix H does not affect the arrangement of code bits of the LDPC code.

In addition, the column permutation of Formula (12) corresponds to the parity interleaving when the information length K is set to 60, the unit size P is set to 5, and the divisor q (=M/P) of the parity length M (herein, 30) is set to 6 in the above-described parity interleaving in which the (K+qx+y+1)-th code bit is interleaved at the position of the (K+Py+x+1)-th code bit.

Therefore, the check matrix H′ of FIG. 202 is a transformed check matrix obtained by performing at least column permutation of permuting the (K+qx+y+1)-th column of the check matrix (hereinafter, appropriately referred to as the original check matrix) H of FIG. 201 to the (K+Py+x+1)-th column.

By multiplying the LDPC code of the original check matrix H of FIG. 201 by a result obtained by performing the same permutation as that of Formula (12) on the transformed check matrix H′ of FIG. 202, a zero vector is output. That is, if the row vector obtained by performing the column permutation of Formula (12) on the row vector c as the LDPC code (one code word) of the original check matrix H is indicated by c′, according to the properties of the check matrix, the Hc^(T) becomes a zero vector, and thus, the H′c′T naturally also becomes a zero vector.

From the above description, the transformed check matrix H′ of FIG. 202 is a check matrix of the LDPC code c′ obtained by performing the column permutation of Formula (12) on the LDPC code c of the original check matrix H.

Therefore, by performing the column permutation of Formula (12) on the LDPC code c of original check matrix H, decoding (LDPC decoding) the LDPC code c′ after the column permutation by using the transformed check matrix H′ of FIG. 202, and performing reverse permutation of the column permutation of Formula (12) on the decoding result, it is possible to obtain the decoding result similar to that of the case of decoding the LDPC code of the original check matrix H by using the check matrix H.

FIG. 203 is a diagram illustrating the transformed check matrix H′ of FIG. 202, which is spaced in units of 5×5 matrices.

In FIG. 203, the transformed check matrix H′ is represented by a combination of 5×5 (=P×P) unit matrices having a unit size P, matrices (hereinafter, appropriately referred to quasi-unit matrices) in which one or more of 1's of the unit matrix become 0, matrices (hereinafter, appropriately referred to as shift matrices) obtained by cyclically shifting of the unit matrix or the quasi-unit matrix, matrices (hereinafter, appropriately referred to as summatrices), each of which is a sum of two or more of the unit matrices, the quasi-unit matrices, or the shift matrices, and 5×5 zero matrices.

The transformed check matrix H′ of FIG. 203 may include 5×5 unit matrices, 5×5 quasi-unit matrices, 5×5 shift matrices, 5×5 summatrices, and 5×5 zero matrices. Therefore, hereinafter, these 5×5 matrices (unit matrices, quasi-unit matrices, shift matrices, sum matrices, and zero matrices) constituting the transformed check matrix H′ are appropriately referred to as configuration matrices.

For the decoding of the LDPC code of the check matrix indicated by a P×P configuration matrix, an architecture that simultaneously performs P check node operations and variable node operations can be used.

FIG. 204 is a block diagram illustrating a configuration example of a decoding device that performs such decoding.

That is, FIG. 204 illustrates the configuration example of the decoding device that performs the decoding of the LDPC code by using the transformed check matrix H′ of FIG. 203 obtained by performing at least the column permutation of Formula (12) on the original check matrix H of FIG. 201.

The decoding device illustrated in FIG. 204 includes a branch data storage memory 300 including six FIFOs 300 ₁ to 300 ₆, a selector 301 for selecting the FIFOs 300 ₁ to 300 ₆, a check node calculation unit 302, two cyclic shift circuits 303 and 308, a branch data storage memory 304 including 18 FIFOs 304 ₁ to 304 ₁₈, a selector 305 for selecting the FIFOs 304 ₁ to 304 ₁₈, a received data memory 306 for storing received data, a variable node calculation unit 307, a decoded word calculation unit 309, a received data rearrangement unit 310, and a decoded data rearrangement unit 311.

First, a method of storing data in the branch data storage memories 300 and 304 will be described.

The branch data storage memory 300 includes six FIFOs 300 ₁ to 300 ₆ of which the number is obtained by dividing the number 30 of rows of the transformed check matrix H′ of FIG. 203 by the number 5 of rows (unit size P) of the configuration matrix. The FIFO 300 _(y) (y=1, 2, . . . , 6) includes a plurality of stages of storage areas, and for each stage storage area, messages corresponding to five branches of which the number is the number of rows and the number of columns of the configuration matrix (unit size P) can be read and written simultaneously. In addition, the number of stages of the storage areas of the FIFO 300 _(y) is 9, which is the maximum number of 1's (Hamming weights) in the row direction of the transformed check matrix of FIG. 203.

The FIFO 300 ₁ stores the data (message v_(i) from the variable node) corresponding to the positions of 1's in the first to fifth rows of the transformed check matrix H′ in FIG. 203 in the form where all the rows are packed in the horizontal direction (in the form ignoring 0). That is, if the j-th row and the i-th column are denoted by (j, i), the first stage storage area of the FIFO 300 ₁ stores the data corresponding to the positions of 1's of the 5×5 unit matrix of (1, 1) to (5, 5) of the transformed check matrix H′. The second stage storage area stores the data corresponding to the positions of 1's of the shift matrix (the shift matrix obtained by cyclically shifting the 5×5 unit matrix in the right direction by 3) of (1, 21) to (5, 25) of the transformed check matrix H′. Similarly, the third to eighth stage storage areas also stores the data in association with the transformed check matrix H′. Then, the ninth stage storage area stores the data corresponding to the positions of 1 's of the shift matrix (the shift matrix obtained by cyclically shifting to the left by 1 by replacing 1 in the first row of the 5×5 unit matrix with 0) of (1, 86) to (5, 90) of the transformed check matrix H′.

The FIFO 300 ₂ stores the data corresponding to the positions of 1's in the 6th to 10th rows of the transformed check matrix H′ of FIG. 203. That is, the first stage storage area of the FIFO 300 ₂ stores the data corresponding to the positions of 1's of the first shift matrix constituting the sum matrix (the sum matrix which is the sum of the first shift matrix obtained by cyclically shifting the 5×5 unit matrix by one to the right and the second shift matrix obtained by cyclically shifting the 5×5 unit matrix by two to the right) of (6, 1) to (10, 5) of the transformed check matrix H′. In addition, the second stage storage area stores the data corresponding to the positions of 1's of the second shift matrix constituting the sum matrix of (6, 1) to (10, 5) of the transformed check matrix H′.

That is, for a configuration matrix having a weight of 2 or more, when the configuration matrix is represented in the form of a sum of a plurality of matrices among P×P unit matrices having a weight of 1, quasi-unit matrices in which one or more of the elements of 1's of the unit matrix becomes 0, or shift matrices obtained by cyclically shifting the unit matrix or the quasi-unit matrix, the data (messages corresponding to branches belonging to the unit matrices, the quasi-unit matrices, or the shift matrices) corresponding to the positions of 1's of the unit matrices having a weight of 1, the quasi-unit matrices, or the shift matrices are stored in the same address (the same FIFO among the FIFOs 300 ₁ to 300 ₆).

Hereinafter, the third to ninth stage storage areas also store the data in association with the transformed check matrix H′.

Similarly, the FIFOs 300 ₃ to 300 ₆ store the data in association with the transformed check matrix H′.

The branch data storage memory 304 includes 18 FIFOs 304 ₁ to 304 ₁₈ of which the number is obtained by dividing the number 90 of columns of the transformed check matrix H′ by the number 5 of columns (unit size P) of the configuration matrix. The FIFO 304 _(x) (x=1, 2, . . . , 18) includes a plurality of storage areas, and for each stage storage areas, messages corresponding to five branches of which the number is the number of rows and the number of columns of the configuration matrix (unit size P) can be read and written simultaneously.

The FIFO 304 ₁ stores the data (message u_(j) from the check node) corresponding to the positions of 1's in the first to fifth columns of the transformed check matrix H′ of FIG. 203 in the form where all the columns are packed in the vertical direction (in the form of ignoring 0). That is, the first stage storage area of the FIFO 304 ₁ stores the data corresponding to the positions of 1's of the 5×5 unit matrix of (1, 1) to (5, 5) of the transformed check matrix H′. The second stage storage area stores the data corresponding to the positions of 1's of the first shift matrix constituting the sum matrix (the sum matrix which is the sum of the first shift matrix obtained by cyclically shifting the 5×5 unit matrix to the right by one and the second shift matrix obtained by cyclically shifting the 5×5 unit matrix to the right by two) of (6, 1) to (10, 5) of the transformed check matrix H′. In addition, the third stage storage area also stores the data corresponding to the positions of 1's of the second shift matrix constituting the sum matrix of (6, 1) to (10, 5) of the transformed check matrix H′.

That is, for a configuration matrix having a weight of 2 or more, when the configuration matrix is represented in the form of a sum of a plurality of matrices among P×P unit matrices having a weight of 1, quasi-unit matrices in which one or more of the elements of 1's of the unit matrix becomes 0, or shift matrices obtained by cyclically shifting the unit matrix or the quasi-unit matrix, the data (messages corresponding to branches belonging to the unit matrices, the quasi-unit matrices, or the shift matrices) corresponding to the positions of 1's of the unit matrices having a weight of 1, the quasi-unit matrices, or the shift matrices are stored in the same address (the same FIFO among the FIFOs 304 ₁ to 304 ₁₈).

Hereinafter, the fourth and fifth stage storage areas also store the data in association with the transformed check matrix H′. The number of stages of the storage areas of the FIFO 304 ₁ is 5, which is the maximum number of 1's (Hamming weights) in the row direction in the first to fifth columns of the transformed check matrix H′.

Similarly, the FIFOs 304 ₂ and 304 ₃ also store the data in association with the transformed check matrix H′, and each has a length (number of stages) of 5. Similarly, the FIFOs 304 ₄ to 304 ₁₂ also store the data in association with the transformed check matrix H′, and each has a length of 3. Similarly, the FIFOs 304 ₁₃ to 304 ₁₈ also store the data in association with the transformed check matrix H′, and each has a length of 2.

Next, the operations of the decoding device in FIG. 204 will be described.

The branch data storage memory 300 includes six FIFOs 300 ₁ to 300 ₆ and selects the FIFOs for storing the data from the FIFOs 300 ₁ to 300 ₆ according to information (matrix data) D312 on which rows of the transformed check matrix H′ of FIG. 203 the five messages D311 supplied from the cyclic shift circuit 308 in the previous stage belong to and collectively and sequentially stores the five messages D311 in the selected FIFOs. In addition, when reading the data, the branch data storage memory 300 sequentially reads the five messages D300 ₁ from the FIFO 300 ₁ and supplies the messages to the selector 301 of the next stage. The branch data storage memory 300 sequentially reads the messages from the FIFOs 300 ₂ to 300 ₆ after the end of the reading of the messages from the FIFO 300 ₁ and supplies the messages to the selector 301.

The selector 301 selects five messages from the FIFO, from which the data is currently being read, among the FIFOs 300 ₁ to 300 ₆ according to the selection signal D301 and supplies the messages as the messages D302 to the check node calculation unit 302.

The check node calculation unit 302 includes five check node calculators 302 ₁ to 302 ₅, and The check node calculation unit 302 performs the check node operation by using messages D302 (D302 ₁ to D302 ₅) (messages v_(i) of Formula (7)) supplied through the selector 301 according to Formula (7) and supplies five messages D303 (D303 ₁ to D303 ₅) (messages u of Formula (7)) obtained as a result of the check node operation to the cyclic shift circuit 303.

The cyclic shift circuit 303 cyclically shifts the five messages D303 ₁ to D303 ₅ obtained by the check node calculation unit 302 on the basis of information (matrix data) D305 as to which times of cyclically shifting are performed on the unit matrix (or quasi-unit matrix) in the transformed check matrix H′ in which corresponding branches are original and supplies messages D304 obtained as a result thereof to the branch data storage memory 304.

The branch data storage memory 304 includes 18 FIFOs 304 ₁ to 304 ₁₈ and selects the FIFOs for storing the data from the FIFOs 304 ₁ to 304 ₁₈ according to the information D305 on which rows of the transformed check matrix H′ the five messages D304 supplied from the cyclic shift circuit 303 in the previous stage belong to and collectively and sequentially stores the five messages D304 in the selected FIFOs. In addition, when reading the data, the branch data storage memory 304 sequentially reads five messages D306 ₁ from the FIFO 304 ₁ and supplies the messages to the selector 305 of the next stage. The branch data storage memory 304 sequentially reads the messages from the FIFOs 304 ₂ to 304 ₁₈ and supplies the messages to the selector 305 after the end of the reading of the data from the FIFO 304 ₁.

The selector 305 selects five messages from the FIFO from which the data is currently being read, among the FIFOs 304 ₁ to 304 ₁₈ according to the selection signal D307 and supplies the messages as messages D308 to the variable node calculation unit 307 and the decoded word calculation unit 309.

On the other hand, the received data rearrangement unit 310 rearranges the LDPC code D313 corresponding to the check matrix H of FIG. 201 received via the communication line 13 by performing the column permutation of Formula (12) and supplies a received data D314 to the received data memory 306. The received data memory 306 calculates and stores reception LLRs (log likelihood ratios) from the received data D314 supplied from the received data rearrangement unit 310, groups the five reception LLRs into reception values D309, and supplies the reception values to the variable node calculation unit 307 and the decoded word calculation unit 309.

The variable node calculation unit 307 includes five variable node calculation units 307 ₁ to 307 ₅ and performs the variable node operation according to Formula (1) by using the messages D308 (D308 ₁ to D308 ₅) (messages u_(j) of Formula (1)) supplied through the selector 305 and the five reception values D309 (the reception values u_(0i) of Formula (1)) supplied from the received data memory 306 and supplies the messages D310 (D310 ₁ to D310 ₅) obtained as a result of the operation (messages v_(i) of Formula (1)) to the cyclic shift circuit 308.

The cyclic shift circuit 308 cyclically shifts the messages D310 ₁ to D310 ₅ calculated by the variable node calculation unit 307 on the basis of information as to which times of cyclically shifting are performed on the unit matrix (or quasi-unit matrix) in the transformed check matrix H′ in which corresponding branches are original and supplies messages D311 obtained as a result thereof to the branch data storage memory 300.

By one cycle of the above operations, one decoding (variable node operation and check node operation) of the LDPC code can be performed. After the decoding the LDPC code a predetermined number of times, the decoding device of FIG. 204 obtains and outputs a final decoding result in the decoded word calculation unit 309 and the decoded data rearrangement unit 311.

That is, the decoded word calculation unit 309 includes five decoded word calculators 309 ₁ to 309 ₅, and the decoded word calculation unit 309 calculates the decoding result (decoded word) on the basis of Formula (5) as the final stage of multiple times of decoding by using the five messages D308 (D308 ₁ to D308 ₅) (messages u_(j) of Formula (5)) output from the selector 305 and the five reception values D309 (reception values u_(0i) of Formula (5)) supplied from the received data memory 306 and supplies a decoded data D315 obtained as a result thereof to the decoded data rearrangement unit 311.

The decoded data rearrangement unit 311 rearranges the order by performing reverse permutation of the column permutation of Formula (12) on the decoded data D315 supplied from the decoded word calculation unit 309 and outputs the final decoding result D316.

As described above, by performing one or both of the row permutation and the column permutation on the check matrix (original check matrix) to be converted into a check matrix (transformed check matrix) that can be represented by a combination of P×P unit matrices, quasi-unit matrices in which one or more of the elements of 1's of the unit matrix becomes 0, shift matrices obtained by cyclically shifting the unit matrix or the quasi-unit matrix, sum matrices, each of which is a sum of a plurality of the unit matrices, the quasi-unit matrices, or the shift matrices, and P×P zero matrices, that is, a combination of configuration matrices, it is possible to adopt an architecture in which P check node operations and P variable node operations are simultaneously performed with the number P being smaller than the number of rows or the number of columns of the check matrix for the decoding of the LDPC code. In the case of adopting an architecture in which P node operations (check node operations and variable node operations) are simultaneously performed with the number P of node operations being smaller than the number of rows or the number of columns of the check matrix, as compared with the case of simultaneously performing the node operations of which the number is equal to the number of rows or the number columns of the check matrix, it is possible to perform a large number of times of repetition of the decoding while refraining an operating frequency within a feasible range.

For example, similarly to the decoding device of FIG. 204, the LDPC decoder 166 constituting the reception device 12 of FIG. 198 performs the LDPC decoding by simultaneously performing P check node operations and P variable node operations.

That is, for simplifying the description, if the check matrix of the LDPC code output from the LDPC encoder 115 constituting the transmission device 11 of FIG. 8 is assumed to be a check matrix H in which the parity matrix has a staircase structure, for example, as illustrated in FIG. 201, the parity interleaver 23 of the transmission device 11 performs the parity interleaving of interleaving the (K+qx+y+1)-th code bit to the position of the (K+Py+x+1)-th code bit in a state where the information length K is set to 60, the unit size P is set to 5, and the divisor q (=M/P) of the parity length M is set to 6, respectively.

Since this parity interleaving corresponds to the column permutation of Formula (12) as described above, the LDPC decoder 166 does not need to perform the column permutation of Formula (12).

For this reason, in the reception device 12 of FIG. 198, as described above, the group-wise deinterleaver 55 supplies, to the LDPC decoder 166, the LDPC code on which the parity deinterleaving has not been performed, that is, the LDPC code in a state where the column permutation of Formula (12) is performed. And the LDPC decoder 166 performs the processing similar to that of the decoding device of FIG. 204 except that the column permutation of Formula (12) is not performed.

That is, FIG. 205 is a diagram illustrating a configuration example of the LDPC decoder 166 of FIG. 198.

In FIG. 205, the LDPC decoder 166 is configured in a manner similar to the decoding device in FIG. 204 except that the received data rearrangement unit 310 of FIG. 204 is not provided. And, the LDPC decoder 166 performs similar processing to that of the decoding device of FIG. 204 except that the column permutation of Formula (12) is not performed, and thus, the description is omitted.

As described above, since the LDPC decoder 166 can be configured without providing the received data rearrangement unit 310, the size can be reduced compared with the decoding device in FIG. 204.

In addition, in FIGS. 201 to 205, for simplifying the description, the code length N of the LDPC code is set to 90, the information length K is set to 60, the unit size (the number of rows and the number of columns of the configuration matrix) P is set to 5, and the divisor q (=M/P) of the parity length M is set to 6, respectively, but the code length N, information length K, unit size P, and the divisor q (=M/P) are not limited to the values described above.

That is, in the transmission device 11 of FIG. 8, the output of the LDPC encoder 115 is an LDPC code, for example, with a code length N of 64800, 16200, 69120, or the like, information length K of N−Pq (=N−M), and a unit size P of 360, and a divisor q of M/P. The LDPC decoder 166 of FIG. 205 can be applied to the case of performing the LDPC decoding by simultaneously performing the P check node operations and the P variable node operations on such an LDPC code.

In addition, after the decoding of the LDPC code in the LDPC decoder 166, in a case where the portion of the parity of the decoding result is unnecessary and only the information bit of the decoding result is output, the LDPC decoder 166 can be configured without the decoded data rearrangement unit 311.

<Configuration Example of Block Deinterleaver 54>

FIG. 206 is a diagram illustrating the block deinterleaving performed by the block deinterleaver 54 of FIG. 199.

In the block deinterleaving, the arrangement of code bits of the LDPC code is returned (restored) to the original arrangement by performing processing reverse to the block interleaving of the block interleaver 25 described with reference to FIG. 117.

That is, in the block deinterleaving, for example, similarly to the block interleaving, the arrangement of the LDPC code is returned to the original arrangement by writing and reading the LDPC code with respect to m columns equal to the bit number m of the symbol.

However, in the block deinterleaving, the writing of the LDPC code is performed in the order of the reading of the LDPC code in the block interleaving. Furthermore, in the block deinterleaving, the reading of the LDPC code is performed in the order of the writing of the LDPC code in the block interleaving.

That is, for the Part 1 of the LDPC code, as illustrated in FIG. 206, the Part 1 of the LDPC code which is configured with m-bit symbol units is written in the row direction from the first row of all m columns. That is, the code bits of the LDPC code, which are m-bit symbols, are written in the row direction.

The writing of the Part 1 in units of m bits is sequentially performed toward the lower row of the m columns, and if the writing of the Part 1 is ended, as illustrated in FIG. 206, the reading of the Part 1 downward from the top of the first column unit of the column is performed from the left towards the right column.

If the reading up to the rightmost column is ended, as illustrated in FIG. 206, the process returns to the leftmost column, and the reading of the Part 1 downward from the top of the second column unit of the column is performed from the left towards the right column, and in a similar manner, the reading of the Part 1 of the LDPC code of one code word is performed.

If the reading of the Part 1 of the LDPC code of one code word is ended, with respect to the Part 2 which are configured with m-bit symbol units, the m-bit symbol units are sequentially concatenated after the Part 1, so that the LDPC code of the symbol units is returned to an arrangement of code bits of the original LDPC code of one code word (LDCP code before the block interleaving).

<Another Configuration Example of Bit Deinterleaver 165>

FIG. 207 is a block diagram illustrating another configuration example of the bit deinterleaver 165 of FIG. 198.

Note that, in the figure, the portions corresponding to the case of FIG. 199 are denoted by the same reference numerals, and the description thereof will be appropriately omitted below.

That is, the bit deinterleaver 165 of FIG. 207 is configured to be similar to the case of FIG. 199 except that a parity deinterleaver 1011 is newly provided.

In FIG. 207, the bit deinterleaver 165 includes a block deinterleaver 54, a group-wise deinterleaver 55, and a parity deinterleaver 1011 and performs bit deinterleaving of code bits of the LDPC code from the demapper 164.

That is, the block deinterleaver 54 performs block deinterleaving (reverse processing of block interleaving) corresponding to the block interleaving performed by the block interleaver 25 of the transmission device 11 on the LDPC code from the demapper 164, that is, performs returning the positions of the code bits replaced by the block interleaving to the original positions and supplies the LDPC code obtained as the result to the group-wise deinterleaver 55.

The group-wise deinterleaver 55 performs group-wise deinterleaving corresponding to the group-wise interleaving as rearrangement processing performed by the group-wise interleaver 24 of the transmission device 11 on the LDPC code from the block deinterleaver 54.

The LDPC code obtained as a result of the group-wise deinterleaving is supplied from the group-wise deinterleaver 55 to the parity deinterleaver 1011.

The parity deinterleaver 1011 performs parity deinterleaving (reverse processing of parity interleaving) corresponding to the parity interleaving performed by the parity interleaver 23 of the transmission device 11 on the code bits after the group-wise deinterleaving in the group-wise deinterleaver 55, that is, performs parity deinterleaving to return the code bits of the LDPC code rearranged by the parity interleaving to the original code bits.

The LDPC code obtained as a result of the parity deinterleaving is supplied from the parity deinterleaver 1011 to the LDPC decoder

Therefore, in the bit deinterleaver 165 of FIG. 207, the LDPC code on which the block deinterleaving, the group-wise deinterleaving, and the parity deinterleaving have be performed, that is, the LDPC code obtained by the LDPC encoding according to the check matrix H is supplied to the LDPC decoder 166.

The LDPC decoder 166 performs the LDPC decoding of the LDPC code from the bit deinterleaver 165 by using the check matrix H used by the LDPC encoder 115 of the transmission device 11 for the LDPC encoding.

That is, for the type-B scheme, the LDPC decoder 166 performs the LDPC decoding of the LDPC code from the bit deinterleaver 165 by using the check matrix H itself (of the type-B scheme) used for the LDPC encoding by the LDPC encoder 115 of the transmission device 11 or the transformed check matrix obtained by performing at least the column permutation corresponding to the parity interleaving on the check matrix H. In addition, for the type-A scheme, the LDPC decoder 166 performs the LDPC decoding of the LDPC code from the bit deinterleaver 165 by using the check matrix (FIG. 28) obtained by the column permutation on the check matrix (FIG. 27) (of the type-A scheme) uses for the LDPC encoding by the LDPC encoder 115 of the transmission device 11 or the transformed check matrix (FIG. 29) obtained by performing the row permutation on the check matrix (FIG. 27) used for the LDPC encoding.

Herein, in FIG. 207, since (the parity deinterleaver 1011 of) the bit deinterleaver 165 supplies the LDPC code obtained by the LDPC encoding according to the check matrix H to the LDPC decoder 166, in a case where the LDPC decoding of the LDPC code is performed by using the check matrix H of type-B scheme itself used for the LDPC encoding by the LDPC encoder 115 of the transmission device 11 or the check matrix (FIG. 28) obtained by performing the column permutation on the check matrix of the type-A scheme (FIG. 27) used for the LDPC encoding, the LDPC decoder 166 may be configured with a decoding device that performs the LDPC decoding, for example, in a full serial decoding scheme in which operations of the messages (check node message and variable node message) are sequentially performed on one node by one node or a decoding device that performs the LDPC decoding in a full parallel decoding scheme in which the operations of the messages simultaneously (in parallel) performed on all nodes.

In addition, in a case where the LDPC decoder 166 performs the LDPC decoding of the LDPC codes by using the transformed check matrix obtained by performing at least the column permutation corresponding to the parity interleaving on the check matrix H of the type-B scheme used for the LDPC encoding by the LDPC encoder 115 of the transmission device 11 or the transformed check matrix (FIG. 29) obtained by performing the row permutation on the check matrix of the type-A scheme (FIG. 27) used for the LDPC encoding, the LDPC decoder 166 may be configured with a decoding device having an architecture that simultaneously performs check node operations and variable node operation P (or a divisor of P other than 1) times as the decoding device (FIG. 204) including the received data rearrangement unit 310 that rearranges the code bits of the LDPC code by performing the column permutation, which is similar to the column permutation (parity interleaving) for obtaining the transformed check matrix, on the LDPC code.

Note that, in FIG. 207, for the convenience of description, the block deinterleaver 54 for performing the block deinterleaving, the group-wise deinterleaver 55 for performing the group-wise deinterleaving, and the parity deinterleaver 1011 for performing the parity deinterleaving are separately configured. However, two or more of the block deinterleaver 54, the group-wise deinterleaver 55, and the parity deinterleaver 1011 can be integrally configured, similarly to the parity interleaver 23, the group-wise interleaver 24, and the block interleaver 25 of the transmission device 11.

<Example of Configuration of Reception System>

FIG. 208 is a block diagram illustrating a first configuration example of a reception system to which the reception device 12 can be applied.

In FIG. 208, the reception system includes an acquisition unit 1101, a transmission-line decoding processing unit 1102, and an information-source decoding processing unit 1103.

The acquisition unit 1101 acquires a signal including an LDPC code obtained by performing at least LDPC encoding on an LDPC target data such as an image data and an audio data of a program via a transmission line (communication line) (not illustrated) of, for example, a terrestrial digital broadcast, a satellite digital broadcast, a CATV network, the Internet, other networks, or the like and supplies the signal to the transmission-line decoding processing unit 1102.

Herein, in a case where the signal acquired by the acquisition unit 1101 is broadcasted from, for example, a broadcasting station via terrestrial wave lines, satellite waves, cable television (CATV) networks, or the like, the acquisition unit 1101 may be configured with a tuner, a set-top box (STB), or the like. In addition, in a case where the signal acquired by the acquisition unit 1101 is transmitted from, for example, the web server by multicast such as internet protocol television (IPTV), the acquisition unit 1101 may be configured with a network interface (I/F of, for example, a network interface card (NIC) or the like.

The transmission-line decoding processing unit 1102 corresponds to the reception device 12. The transmission-line decoding processing unit 1102 performs transmission-line decoding processing including at least processing for correcting an error occurring in the transmission line on the signal acquired by the acquisition unit 1101 via the transmission line and supplies a signal obtained as a result thereof to the information-source decoding processing unit 1103.

That is, the signal acquired by the acquisition unit 1101 via the transmission line is a signal obtained by performing at least error correction coding for correcting an error occurring in the transmission line, and the transmission-line decoding processing unit 1102 performs, for example, transmission-line decoding processing such as error correction processing on such a signal.

Herein, as the error correction coding, for example, there are LDPC encoding, BCH encoding, and the like. Herein, at least the LDPC encoding is performed as the error correction coding.

In addition, the transmission-line decoding processing may include demodulation of a modulated signal and the like.

The information-source decoding processing unit 1103 performs information-source decoding processing including at least processing of decompressing compressed information into original information on the signal on which the transmission-line decoding processing has been performed.

That is, in some cases, in order to reduce the amount of data such as an image and an audio as information, compression encoding for compressing the information may be performed on the signal acquired by the acquisition unit 1101 via the transmission line. In this case, the information-source decoding processing unit 1103 performs information-source decoding processing such as processing (decompression processing) of decompressing compressed information into original information on the signal on which the transmission-line decoding processing has been performed.

In addition, in a case where the compression encoding is not performed on the signal acquired by the acquisition unit 1101 via the transmission line, the information-source decoding processing unit 1103 performs the decompressing process on the compressed information to the original information.

Herein, as the decompression process, for example, there are MPEG decoding and the like. In addition to the decompression processing, the transmission-line decoding processing may include descrambling and the like.

In the reception system configured as described above, in the acquisition unit 1101, for example, the compression encoding such as MPEG encoding is performed on the data such as an image and an audio, and in addition, the signal formed by performing the error correction coding such as LDPC encoding is acquired via the transmission line and supplied to the transmission-line decoding processing unit 1102.

In the transmission-line decoding processing unit 1102, for example, processing similar to that performed by the reception device 12 or the like is performed as transmission-line decoding processing on the signal from the acquisition unit 1101, and a signal obtained as a result thereof is supplied to the information-source decoding processing unit 1103.

In the information-source decoding processing unit 1103, information-source decoding processing such as MPEG decoding is performed on the signal from the transmission-line decoding processing unit 1102, and an image or an audio obtained as a result thereof is output.

The reception system of FIG. 208 as described above can be applied to, for example, a television tuner or the like that receives television broadcasting as digital broadcast.

In addition, each of the acquisition unit 1101, the transmission-line decoding processing unit 1102, and the information-source decoding processing unit 1103 is configured as one independent device (hardware (integrated circuit (IC) or the like) or software module).

In addition, for the acquisition unit 1101, the transmission-line decoding processing unit 1102, and the information-source decoding processing unit 1103, a set of the acquisition unit 1101 and the transmission-line decoding processing unit 1102, a set of the transmission-line decoding processing unit 1102 and the information-source decoding processing unit 1103, and a set of the acquisition unit 1101, the transmission-line decoding processing unit 1102, and the information-source decoding processing unit 1103 can be configured as one independent device.

FIG. 209 is a block diagram illustrating a second configuration example of a reception system to which the reception device 12 can be applied.

In addition, in the figure, the portions corresponding to those of the case of FIG. 208 are denoted by the same reference numerals, and the description thereof will be appropriately omitted below.

The reception system of FIG. 209 is the same as the case of FIG. 208 in that the reception system includes the acquisition unit 1101, the transmission-line decoding processing unit 1102, and the information-source decoding processing unit 1103 and is different from the case of FIG. 208 in that an output unit 1111 is newly provided.

The output unit 1111 is, for example, a display device for displaying an image or a speaker for outputting an audio and outputs an image, an audio, or the like as a signal output from the information-source decoding processing unit 1103. That is, the output unit 1111 displays an image or outputs an audio.

The reception system of FIG. 209 as described above can be applied to, for example, a television (TV) set that receives television broadcasting as digital broadcast, a radio receiver that receives radio broadcast, and the like.

In addition, in a case where compression encoding is not performed on the signal acquired by the acquisition unit 1101, the signal output from the transmission-line decoding processing unit 1102 is supplied to the output unit 1111.

FIG. 210 is a block diagram illustrating a third configuration example of a reception system to which the reception device 12 can be applied.

In addition, in the figure, the portions corresponding to those of the case of FIG. 208 are denoted by the same reference numerals, and the description thereof will be appropriately omitted below.

The reception system of FIG. 210 is the same as the case of FIG. 208 in that the reception system includes the acquisition unit 1101 and the transmission-line decoding processing unit 1102.

However, the reception system of FIG. 210 is different from the case of FIG. 208 in that the information-source decoding processing unit 1103 is not provided and a recording unit 1121 is newly provided.

The recording unit 1121 records a signal (for example, a TS packet of TS of MPEG) output by the transmission-line decoding processing unit 1102 on a recording (storage) medium such as an optical disk, a hard disk (magnetic disk), or a flash memory.

The reception system of FIG. 210 as described above can be applied to a recorder or the like that records television broadcasting.

In addition, in FIG. 210, the reception system is configured by providing the information-source decoding processing unit 1103 and can record the signal after the information-source decoding processing is performed in the information-source decoding processing unit 1103, that is, an image or an audio obtained by decoding in the recording unit 1121.

<One Embodiment of Computer>

Next, a series of processes described above can be performed by hardware or software. In a case where the series of processes are performed by software, a program constituting the software is installed in a general-purpose computer or the like.

Thus, FIG. 211 illustrates a configuration example of an embodiment of a computer in which a program executing the series of processes described above is installed.

The program can be recorded in advance in a hard disk 705 or a ROM 703 as a recording medium built in the computer.

Alternatively, the program can be temporarily or permanently stored (recorded) in a removable recording medium 711 such as a flexible disc, a compact disc read only memory (CD-ROM), a magneto optical disc (MO), a digital versatile disc (DVD), a magnetic disc, or a semiconductor memory. Such removable recording medium 711 can be provided as so-called package software.

Note that, besides the program that is installed on the computer from the removable recording medium 711 as described above, the program may be wirelessly transferred from a download site to the computer via an artificial satellite for digital satellite broadcasting or may be transferred by wire to the computer via a network such as a local area network (LAN) or the Internet, and the computer can receive the program transferred as such by the communication unit 708 and install the program in the built-in hard disk 705.

The computer incorporates a central processing unit (CPU) 702. An input/output interface 710 is connected to the CPU 702 via a bus 701. When a command of operating an input unit 707 including a keyboard, a mouse, a microphone, and the like is input by the user via the input/output interface 710, the CPU 702 executes a program stored in the read only memory (ROM) 703 according to the command. Alternatively, in addition, the CPU 702 loads a program stored in the hard disk 705, a program transferred from a satellite or a network, received by the communication unit 708, and installed in the hard disk 705, or a program read from the removable recording medium 711 mounted on the drive 709 and installed in the hard disk 705 to a random access memory (RAM) 704 and executes the program. Thus, the CPU 702 performs the processing according to the above-described flowchart or the processing performed by the configurations of the above-described block diagrams. Then, the CPU 702 outputs the processing result from the output unit 706 configured with a liquid crystal display (LCD), a speaker, or the like, transmits the processing result from the communication unit 708, or records the processing result on the hard disk 705 or the like, for example, via the input/output interface 710 as necessary.

Herein, in the present specification, processing steps for describing a program for causing a computer to perform various processing are not necessarily processed in time series in accordance with the order described as a flowchart, and the present invention also includes the processing (for example, parallel processing or processing by objects) to be performed in parallel or individually.

In addition, the program may be processed by one computer or may be distributed and processed by a plurality of computers. Furthermore, the program may be transferred to a remote computer for execution.

In addition, the embodiments of the present technology are not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present technology.

For example, the above-described new LDPC code (check matrix initial value table) and GW pattern can be used for a satellite line, a terrestrial wave line, a cable (wired line), and other communication lines 13 (FIG. 7). Furthermore, the new LDPC code and GW pattern can be used for data transmission other than digital broadcasting.

In addition, the effects described in this specification are only examples and not limited, and there may be other effects.

REFERENCE SIGNS LIST

-   11 Transmission device -   12 Reception device -   23 Parity interleaver -   24 Group-wise interleaver -   25 Block interleaver -   54 Block deinterleaver -   55 Group-wise deinterleaver -   111 Mode adaptation/multiplexer -   112 Padder -   113 BB scrambler -   114 BCH encoder -   115 LDPC encoder -   116 Bit interleaver -   117 Mapper -   118 Time interleaver -   119 SISO/MISO encoder -   120 Frequency interleaver -   121 BCH encoder -   122 LDPC encoder -   123 Mapper -   124 Frequency interleaver -   131 Frame builder & resource allocation unit -   132 OFDM generation unit -   151 OFDM processing unit -   152 Frame management unit -   153 Frequency deinterleaver -   154 Demapper -   155 LDPC decoder -   156 BCH decoder -   161 Frequency deinterleaver -   162 SISO/MISO decoder -   163 Time deinterleaver -   164 Demapper -   165 Bit deinterleaver -   166 LDPC decoder -   167 BCH decoder -   168 BB descrambler -   169 Null deletion unit -   170 Demultiplexer -   300 Branch data storage memory -   301 Selector -   302 Check node calculation unit -   303 Cyclic shift circuit -   304 Branch data storage memory -   305 Selector -   306 Received data memory -   307 Variable node calculation unit -   308 Cyclic shift circuit -   309 Decoded word calculation unit -   310 Received data rearrangement unit -   311 Decoded data rearrangement unit -   601 Encoding processing unit -   602 Storage unit -   611 Encoding rate setting unit -   612 Initial value table reading unit -   613 Check matrix generation unit -   614 Information bit reading unit -   615 Encoding parity calculation unit -   616 Control unit -   701 Bus -   702 CPU -   703 ROM -   704 RAM -   705 Hard disk -   706 Output unit -   707 Input unit -   708 Communication unit -   709 Drive -   710 Input/output interface -   711 Removable recording medium -   1001 Reverse replacement unit -   1002 Memory -   1011 Parity deinterleaver -   1101 Acquisition unit -   1102 Transmission-line decoding processing unit -   1103 Information-source decoding processing section -   1111 Output unit -   1121 Recording unit 

The invention claimed is:
 1. A transmission method comprising: an encoding step of performing LDPC encoding on a basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 3/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, wherein in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 138, 38, 106, 76, 172, 27, 150, 95, 44, 187, 64, 18, 28, 98, 180, 101, 149, 146, 126, 26, 93, 178, 186, 70, 104, 131, 19, 45, 102, 122, 152, 66, 63, 173, 9, 55, 25, 1, 154, 85, 5, 51, 43, 82, 86, 151, 148, 48, 190, 179, 62, 60, 94, 174, 142, 39, 169, 170, 47, 125, 33, 128, 162, 2, 129, 57, 79, 118, 114, 69, 78, 167, 11, 136, 99, 155, 90, 21, 119, 10, 52, 91, 115, 185, 6, 110, 88, 96, 181, 143, 0, 160, 124, 130, 183, 71, 121, 182, 68, 191, 3, 32, 40, 189, 41, 156, 35, 159, 58, 89, 29, 67, 17, 109, 30, 111, 12, 46, 65, 177, 53, 77, 74, 56, 184, 15, 141, 135, 54, 163, 14, 145, 139, 134, 59, 147, 87, 107, 7, 61, 36, 113, 103, 188, 24, 165, 137, 22, 42, 49, 83, 73, 50, 161, 20, 166, 127, 157, 108, 171, 37, 72, 176, 112, 123, 144, 34, 175, 168, 117, 80, 81, 8, 31, 133, 92, 164, 132, 97, 158, 84, 100, 140, 16, 105, 23, 75, 13, 153, 116, 4, 120, the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is 126 1125 1373 4698 5254 17832 23701 31126 33867 46596 46794 48392 49352 51151 52100 55162 794 1435 1552 4483 14668 16919 21871 36755 42132 43323 46650 47676 50412 53484 54886 55333 698 1356 1519 5555 6877 8407 8414 14248 17811 22998 28378 40695 46542 52817 53284 55968 457 493 1080 2261 4637 5314 9670 11171 12679 29201 35980 43792 44337 47131 49880 55301 467 721 1484 5326 8676 11727 15221 17477 21390 22224 27074 28845 37670 38917 40996 43851 305 389 526 9156 11091 12367 13337 14299 22072 25367 29827 30710 37688 44321 48351 54663 23 342 1426 5889 7362 8213 8512 10655 14549 15486 26010 30403 32196 36341 37705 45137 123 429 485 4093 6933 11291 11639 12558 20096 22292 24696 32438 34615 38061 40659 51577 920 1086 1257 8839 10010 13126 14367 18612 23252 23777 32883 32982 35684 40534 53318 55947 579 937 1593 2549 12702 17659 19393 20047 25145 27792 30322 33311 39737 42052 50294 53363 116 883 1067 9847 10660 12052 18157 20519 21191 24139 27132 27643 30745 33852 37692 37724 915 1154 1698 5197 5249 13741 25043 29802 31354 32707 33804 36856 39887 41245 42065 50240 317 1304 1770 12854 14018 14061 16657 24029 24408 34493 35322 35755 38593 47428 53811 55008 163 216 719 5541 13996 18754 19287 24293 38575 39520 43058 43395 45390 46665 50706 55269 42 415 1326 2553 7963 14878 17850 21757 22166 32986 39076 39267 46154 46790 52877 53780 593 1511 1515 13942 14258 14432 24537 38229 38251 40975 41350 43490 44880 45278 46574 51442 219 262 955 1978 10654 13021 16873 23340 27412 32762 40024 42723 45976 46603 47761 54095 632 944 1598 12924 17942 18478 26487 28036 42462 43513 44487 44584 48245 53274 54343 55453 501 912 1656 2009 6339 15581 20597 26886 32241 34471 37497 43009 45977 46587 46821 51187 610 713 1619 5176 6122 6445 8044 12220 14126 32911 38647 40715 45111 47872 50111 55027 258 445 1137 4517 5846 7644 15604 16606 16969 17622 20691 34589 35808 43692 45126 49527 612 854 1521 13045 14525 15821 21096 23774 24274 25855 26266 27296 30033 40847 44681 46072 714 876 1365 5836 10004 15778 17044 22417 26397 31508 32354 37917 42049 50828 50947 54052 1338 1595 1718 4722 4981 12275 13632 15276 15547 17668 21645 26616 29044 39417 39669 53539 687 721 1054 5918 10421 13356 15941 17657 20704 21564 23649 35798 36475 46109 46414 49845 734 1635 1666 9737 23679 24394 24784 26917 27334 28772 29454 35246 35512 37169 39638 44309 469 918 1212 3912 10712 13084 13906 14000 16602 18040 18697 25940 30677 44811 50590 52018 70 332 496 6421 19082 19665 25460 27377 27378 31086 36629 37104 37236 37771 38622 40678 48 142 1668 2102 3421 10462 13086 13671 24889 36914 37586 40166 42935 49052 49205 52170 294 616 840 2360 5386 7278 10202 15133 24149 24629 27338 28672 31892 39559 50438 50453 517 946 1043 2563 3416 6620 8572 10920 31906 32685 36852 40521 46898 48369 48700 49210 1325 1424 1741 11692 11761 19152 19732 28863 30563 34985 42394 44802 49339 54524 55731 664 1340 1437 9442 10378 12176 18760 19872 21648 34682 37784 40545 44808 47558 53061 378 705 1356 16007 16336 19543 21682 28716 30262 34500 40335 44238 48274 50341 52887 999 1202 1328 10688 11514 11724 15674 21039 35182 36272 41441 42542 52517 54945 56157 247 384 1270 6610 10335 24421 25984 27761 38728 41010 46216 46892 47392 48394 51471 10091 10124 12187 13741 18018 20438 21412 24163 35862 36925 37532 46234 7860 8123 8712 17553 20624 29410 29697 29853 43483 43603 53476 53737 11547 11741 19045 20400 23052 28251 32038 44283 50596 53622 55875 55888 3825 11292 11723 13819 26483 28571 33319 33721 34911 37766 47843 48667 10114 10336 14710 15586 19531 22471 27945 28397 45637 46131 47760
 52375. 2. A reception device comprising a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, wherein the transmission device includes: an encoding unit that performs LDPC encoding on a basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 3/16, a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 138, 38, 106, 76, 172, 27, 150, 95, 44, 187, 64, 18, 28, 98, 180, 101, 149, 146, 126, 26, 93, 178, 186, 70, 104, 131, 19, 45, 102, 122, 152, 66, 63, 173, 9, 55, 25, 1, 154, 85, 5, 51, 43, 82, 86, 151, 148, 48, 190, 179, 62, 60, 94, 174, 142, 39, 169, 170, 47, 125, 33, 128, 162, 2, 129, 57, 79, 118, 114, 69, 78, 167, 11, 136, 99, 155, 90, 21, 119, 10, 52, 91, 115, 185, 6, 110, 88, 96, 181, 143, 0, 160, 124, 130, 183, 71, 121, 182, 68, 191, 3, 32, 40, 189, 41, 156, 35, 159, 58, 89, 29, 67, 17, 109, 30, 111, 12, 46, 65, 177, 53, 77, 74, 56, 184, 15, 141, 135, 54, 163, 14, 145, 139, 134, 59, 147, 87, 107, 7, 61, 36, 113, 103, 188, 24, 165, 137, 22, 42, 49, 83, 73, 50, 161, 20, 166, 127, 157, 108, 171, 37, 72, 176, 112, 123, 144, 34, 175, 168, 117, 80, 81, 8, 31, 133, 92, 164, 132, 97, 158, 84, 100, 140, 16, 105, 23, 75, 13, 153, 116, 4, 120, the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is 126 1125 1373 4698 5254 17832 23701 31126 33867 46596 46794 48392 49352 51151 52100 55162 794 1435 1552 4483 14668 16919 21871 36755 42132 43323 46650 47676 50412 53484 54886 55333 698 1356 1519 5555 6877 8407 8414 14248 17811 22998 28378 40695 46542 52817 53284 55968 457 493 1080 2261 4637 5314 9670 11171 12679 29201 35980 43792 44337 47131 49880 55301 467 721 1484 5326 8676 11727 15221 17477 21390 22224 27074 28845 37670 38917 40996 43851 305 389 526 9156 11091 12367 13337 14299 22072 25367 29827 30710 37688 44321 48351 54663 23 342 1426 5889 7362 8213 8512 10655 14549 15486 26010 30403 32196 36341 37705 45137 123 429 485 4093 6933 11291 11639 12558 20096 22292 24696 32438 34615 38061 40659 51577 920 1086 1257 8839 10010 13126 14367 18612 23252 23777 32883 32982 35684 40534 53318 55947 579 937 1593 2549 12702 17659 19393 20047 25145 27792 30322 33311 39737 42052 50294 53363 116 883 1067 9847 10660 12052 18157 20519 21191 24139 27132 27643 30745 33852 37692 37724 915 1154 1698 5197 5249 13741 25043 29802 31354 32707 33804 36856 39887 41245 42065 50240 317 1304 1770 12854 14018 14061 16657 24029 24408 34493 35322 35755 38593 47428 53811 55008 163 216 719 5541 13996 18754 19287 24293 38575 39520 43058 43395 45390 46665 50706 55269 42 415 1326 2553 7963 14878 17850 21757 22166 32986 39076 39267 46154 46790 52877 53780 593 1511 1515 13942 14258 14432 24537 38229 38251 40975 41350 43490 44880 45278 46574 51442 219 262 955 1978 10654 13021 16873 23340 27412 32762 40024 42723 45976 46603 47761 54095 632 944 1598 12924 17942 18478 26487 28036 42462 43513 44487 44584 48245 53274 54343 55453 501 912 1656 2009 6339 15581 20597 26886 32241 34471 37497 43009 45977 46587 46821 51187 610 713 1619 5176 6122 6445 8044 12220 14126 32911 38647 40715 45111 47872 50111 55027 258 445 1137 4517 5846 7644 15604 16606 16969 17622 20691 34589 35808 43692 45126 49527 612 854 1521 13045 14525 15821 21096 23774 24274 25855 26266 27296 30033 40847 44681 46072 714 876 1365 5836 10004 15778 17044 22417 26397 31508 32354 37917 42049 50828 50947 54052 1338 1595 1718 4722 4981 12275 13632 15276 15547 17668 21645 26616 29044 39417 39669 53539 687 721 1054 5918 10421 13356 15941 17657 20704 21564 23649 35798 36475 46109 46414 49845 734 1635 1666 9737 23679 24394 24784 26917 27334 28772 29454 35246 35512 37169 39638 44309 469 918 1212 3912 10712 13084 13906 14000 16602 18040 18697 25940 30677 44811 50590 52018 70 332 496 6421 19082 19665 25460 27377 27378 31086 36629 37104 37236 37771 38622 40678 48 142 1668 2102 3421 10462 13086 13671 24889 36914 37586 40166 42935 49052 49205 52170 294 616 840 2360 5386 7278 10202 15133 24149 24629 27338 28672 31892 39559 50438 50453 517 946 1043 2563 3416 6620 8572 10920 31906 32685 36852 40521 46898 48369 48700 49210 1325 1424 1741 11692 11761 19152 19732 28863 30563 34985 42394 44802 49339 54524 55731 664 1340 1437 9442 10378 12176 18760 19872 21648 34682 37784 40545 44808 47558 53061 378 705 1356 16007 16336 19543 21682 28716 30262 34500 40335 44238 48274 50341 52887 999 1202 1328 10688 11514 11724 15674 21039 35182 36272 41441 42542 52517 54945 56157 247 384 1270 6610 10335 24421 25984 27761 38728 41010 46216 46892 47392 48394 51471 10091 10124 12187 13741 18018 20438 21412 24163 35862 36925 37532 46234 7860 8123 8712 17553 20624 29410 29697 29853 43483 43603 53476 53737 11547 11741 19045 20400 23052 28251 32038 44283 50596 53622 55875 55888 3825 11292 11723 13819 26483 28571 33319 33721 34911 37766 47843 48667 10114 10336 14710 15586 19531 22471 27945 28397 45637 46131 47760
 52375. 3. A transmission method comprising: an encoding step of performing LDPC encoding on a basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 5/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, wherein in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 37, 136, 161, 62, 163, 129, 160, 73, 76, 66, 34, 162, 122, 5, 87, 94, 50, 105, 132, 32, 121, 47, 74, 189, 110, 45, 75, 175, 17, 29, 108, 191, 1, 153, 20, 113, 61, 42, 51, 2, 165, 124, 43, 186, 40, 86, 168, 180, 155, 16, 93, 26, 166, 119, 159, 56, 12, 44, 46, 143, 49, 25, 176, 158, 92, 147, 54, 172, 182, 64, 157, 112, 38, 39, 11, 6, 127, 48, 151, 82, 4, 36, 183, 88, 126, 117, 111, 188, 138, 65, 70, 170, 133, 137, 146, 128, 114, 148, 141, 125, 10, 41, 116, 33, 99, 81, 187, 130, 131, 107, 60, 90, 173, 13, 71, 15, 106, 3, 149, 154, 181, 174, 190, 27, 177, 18, 21, 22, 83, 91, 150, 14, 96, 53, 0, 145, 67, 68, 144, 184, 59, 23, 118, 115, 135, 55, 134, 102, 8, 169, 85, 156, 97, 63, 104, 95, 52, 98, 139, 24, 78, 179, 19, 28, 69, 58, 109, 57, 164, 31, 84, 140, 103, 77, 123, 171, 72, 79, 152, 35, 80, 7, 185, 167, 9, 100, 142, 89, 30, 120, 178, 101, the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is 152 1634 7484 23081 24142 26799 33620 40989 41902 44319 44378 45067 140 701 5137 7313 12672 16929 20359 27052 30236 33846 36254 46973 748 769 2891 7812 9964 15629 19104 20551 25796 28144 31518 34124 542 976 2279 18904 20877 24190 25903 28129 36804 41152 41957 46888 173 960 2926 11682 12304 13284 18037 22702 30255 33718 34073 37152 78 1487 4898 7472 8033 10631 11732 19334 24577 34586 38651 43639 594 1095 1857 2368 8909 17295 17546 21865 23257 31273 37013 41454 72 419 1596 7849 16093 23167 26923 31883 36092 40348 44500 866 1120 1568 1986 3532 20094 21663 26664 26970 33542 42578 868 917 1216 12018 15402 20691 24736 33133 36692 40276 46616 955 1070 1749 7988 10235 19174 22733 24283 27985 38200 44029 613 1729 1787 19542 21227 21376 31057 36104 36874 38078 42445 86 1555 1644 4633 14402 14997 25724 31382 31911 32224 43900 353 1132 1246 5544 7248 17887 25769 27008 28773 33188 44663 600 958 1376 6417 6814 17587 20680 25376 29522 31396 40526 179 528 1472 2481 5589 15696 20148 28040 29690 32370 42163 122 144 681 6613 11230 20862 26396 27737 35928 39396 42713 934 1256 1420 3881 4487 5830 7897 9587 17940 40333 41925 622 1458 1490 16541 18443 19401 24860 26981 28157 32875 38755 1017 1143 1511 2169 17322 24662 25971 29149 31450 31670 34779 935 1084 1534 2918 10596 11534 17476 27269 30344 31104 37975 173 532 1766 8001 10483 17002 19002 26759 31006 43466 47443 221 610 1795 9197 11770 12793 14875 30177 30610 42274 43888 188 439 1332 7030 9246 15150 26060 26541 27190 28259 36763 812 1643 1750 7446 7888 7995 18804 21646 28995 30727 39065 44 481 555 5618 9621 9873 19182 22059 42510 45343 46058 156 532 1799 6258 18733 19988 23237 27657 30835 34738 39503 1128 1553 1790 8372 11543 13764 17062 28627 38502 40796 42461 564 777 1286 3446 5566 12105 16038 18918 21802 25954 28137 1167 1178 1770 4151 11422 11833 16823 17799 19188 22517 29979 576 638 1364 12257 22028 24243 24297 31788 36398 38409 47211 334 592 940 2865 12075 12708 21452 31961 32150 35723 46278 1205 1267 1721 9293 18685 18917 23490 27678 37645 40114 45733 189 628 821 17066 19218 21462 25452 26858 38408 38941 42354 190 951 1019 5572 7135 15647 32613 33863 33981 35670 43727 84 1003 1597 12597 15567 21221 21891 23151 23964 24816 46178 756 1262 1345 6694 6893 9300 9497 17950 19082 35668 38447 848 948 1560 6591 12529 12535 20567 23882 34481 46531 46541 504 631 777 10585 12330 13822 15388 23332 27688 35955 38051 676 1484 1575 2215 5830 6049 13558 25034 33602 35663 41025 1298 1427 1732 13930 15611 19462 20975 23200 30460 30682 34883 1491 1593 1615 4289 7010 10264 21047 26704 27024 29658 46766 969 1730 1748 2217 7181 7623 15860 21332 28133 28998 36077 302 1216 1374 5177 6849 7239 10255 34952 37908 39911 41738 220 362 1491 5235 5439 22708 29228 29481 33272 36831 46487 4 728 1279 4579 8325 8505 27604 31437 33574 41716 45082 472 735 1558 4454 6957 14867 18307 22437 38304 42054 45307 85 466 851 3669 7119 32748 32845 41914 42595 42600 45101 52 553 824 2994 4569 12505 24738 33258 37121 43381 44753 37 495 1553 7684 8908 12412 15563 16461 17872 29292 30619 254 1057 1481 9971 18408 19815 28569 29164 39281 42723 45604 16 1213 1614 4352 8091 8847 10022 24394 35661 43800 44362 395 750 888 2582 3772 4151 26025 36367 42326 42673 47393 862 1379 1441 6413 25621 28378 34869 35491 41774 44165 45411 46 213 1597 2771 4694 4923 17101 17212 19347 22002 43226 1339 1544 1610 13522 14840 15355 29399 30125 33685 36350 37672 251 1162 1260 9766 13137 34769 36646 43313 43736 43828 45151 214 1002 1688 5357 19091 19213 24460 28843 32869 35013 39791 646 733 1735 11175 11336 12043 22962 33892 35646 37116 38655 293 927 1064 4818 5842 10983 12871 17804 33127 41604 46588 10927 15514 22748 34850 37645 40669 41583 44090 3329 7548 8092 11659 16832 35304 46738 46888 3510 5915 9603 30333 37198 42866 44361 46416 2575 5311 9421 13410 15375 34017 37136 43990 12468 14492 24417 26394 38565 38936 41899
 45593. 4. A reception device comprising a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, wherein the transmission device includes: an encoding unit that performs LDPC encoding on a basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 5/16; a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 37, 136, 161, 62, 163, 129, 160, 73, 76, 66, 34, 162, 122, 5, 87, 94, 50, 105, 132, 32, 121, 47, 74, 189, 110, 45, 75, 175, 17, 29, 108, 191, 1, 153, 20, 113, 61, 42, 51, 2, 165, 124, 43, 186, 40, 86, 168, 180, 155, 16, 93, 26, 166, 119, 159, 56, 12, 44, 46, 143, 49, 25, 176, 158, 92, 147, 54, 172, 182, 64, 157, 112, 38, 39, 11, 6, 127, 48, 151, 82, 4, 36, 183, 88, 126, 117, 111, 188, 138, 65, 70, 170, 133, 137, 146, 128, 114, 148, 141, 125, 10, 41, 116, 33, 99, 81, 187, 130, 131, 107, 60, 90, 173, 13, 71, 15, 106, 3, 149, 154, 181, 174, 190, 27, 177, 18, 21, 22, 83, 91, 150, 14, 96, 53, 0, 145, 67, 68, 144, 184, 59, 23, 118, 115, 135, 55, 134, 102, 8, 169, 85, 156, 97, 63, 104, 95, 52, 98, 139, 24, 78, 179, 19, 28, 69, 58, 109, 57, 164, 31, 84, 140, 103, 77, 123, 171, 72, 79, 152, 35, 80, 7, 185, 167, 9, 100, 142, 89, 30, 120, 178, 101, the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is 152 1634 7484 23081 24142 26799 33620 40989 41902 44319 44378 45067 140 701 5137 7313 12672 16929 20359 27052 30236 33846 36254 46973 748 769 2891 7812 9964 15629 19104 20551 25796 28144 31518 34124 542 976 2279 18904 20877 24190 25903 28129 36804 41152 41957 46888 173 960 2926 11682 12304 13284 18037 22702 30255 33718 34073 37152 78 1487 4898 7472 8033 10631 11732 19334 24577 34586 38651 43639 594 1095 1857 2368 8909 17295 17546 21865 23257 31273 37013 41454 72 419 1596 7849 16093 23167 26923 31883 36092 40348 44500 866 1120 1568 1986 3532 20094 21663 26664 26970 33542 42578 868 917 1216 12018 15402 20691 24736 33133 36692 40276 46616 955 1070 1749 7988 10235 19174 22733 24283 27985 38200 44029 613 1729 1787 19542 21227 21376 31057 36104 36874 38078 42445 86 1555 1644 4633 14402 14997 25724 31382 31911 32224 43900 353 1132 1246 5544 7248 17887 25769 27008 28773 33188 44663 600 958 1376 6417 6814 17587 20680 25376 29522 31396 40526 179 528 1472 2481 5589 15696 20148 28040 29690 32370 42163 122 144 681 6613 11230 20862 26396 27737 35928 39396 42713 934 1256 1420 3881 4487 5830 7897 9587 17940 40333 41925 622 1458 1490 16541 18443 19401 24860 26981 28157 32875 38755 1017 1143 1511 2169 17322 24662 25971 29149 31450 31670 34779 935 1084 1534 2918 10596 11534 17476 27269 30344 31104 37975 173 532 1766 8001 10483 17002 19002 26759 31006 43466 47443 221 610 1795 9197 11770 12793 14875 30177 30610 42274 43888 188 439 1332 7030 9246 15150 26060 26541 27190 28259 36763 812 1643 1750 7446 7888 7995 18804 21646 28995 30727 39065 44 481 555 5618 9621 9873 19182 22059 42510 45343 46058 156 532 1799 6258 18733 19988 23237 27657 30835 34738 39503 1128 1553 1790 8372 11543 13764 17062 28627 38502 40796 42461 564 777 1286 3446 5566 12105 16038 18918 21802 25954 28137 1167 1178 1770 4151 11422 11833 16823 17799 19188 22517 29979 576 638 1364 12257 22028 24243 24297 31788 36398 38409 47211 334 592 940 2865 12075 12708 21452 31961 32150 35723 46278 1205 1267 1721 9293 18685 18917 23490 27678 37645 40114 45733 189 628 821 17066 19218 21462 25452 26858 38408 38941 42354 190 951 1019 5572 7135 15647 32613 33863 33981 35670 43727 84 1003 1597 12597 15567 21221 21891 23151 23964 24816 46178 756 1262 1345 6694 6893 9300 9497 17950 19082 35668 38447 848 948 1560 6591 12529 12535 20567 23882 34481 46531 46541 504 631 777 10585 12330 13822 15388 23332 27688 35955 38051 676 1484 1575 2215 5830 6049 13558 25034 33602 35663 41025 1298 1427 1732 13930 15611 19462 20975 23200 30460 30682 34883 1491 1593 1615 4289 7010 10264 21047 26704 27024 29658 46766 969 1730 1748 2217 7181 7623 15860 21332 28133 28998 36077 302 1216 1374 5177 6849 7239 10255 34952 37908 39911 41738 220 362 1491 5235 5439 22708 29228 29481 33272 36831 46487 4 728 1279 4579 8325 8505 27604 31437 33574 41716 45082 472 735 1558 4454 6957 14867 18307 22437 38304 42054 45307 85 466 851 3669 7119 32748 32845 41914 42595 42600 45101 52 553 824 2994 4569 12505 24738 33258 37121 43381 44753 37 495 1553 7684 8908 12412 15563 16461 17872 29292 30619 254 1057 1481 9971 18408 19815 28569 29164 39281 42723 45604 16 1213 1614 4352 8091 8847 10022 24394 35661 43800 44362 395 750 888 2582 3772 4151 26025 36367 42326 42673 47393 862 1379 1441 6413 25621 28378 34869 35491 41774 44165 45411 46 213 1597 2771 4694 4923 17101 17212 19347 22002 43226 1339 1544 1610 13522 14840 15355 29399 30125 33685 36350 37672 251 1162 1260 9766 13137 34769 36646 43313 43736 43828 45151 214 1002 1688 5357 19091 19213 24460 28843 32869 35013 39791 646 733 1735 11175 11336 12043 22962 33892 35646 37116 38655 293 927 1064 4818 5842 10983 12871 17804 33127 41604 46588 10927 15514 22748 34850 37645 40669 41583 44090 3329 7548 8092 11659 16832 35304 46738 46888 3510 5915 9603 30333 37198 42866 44361 46416 2575 5311 9421 13410 15375 34017 37136 43990 12468 14492 24417 26394 38565 38936 41899
 45593. 5. A transmission method comprising: an encoding step of performing LDPC encoding on a basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 7/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, wherein in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 148, 189, 3, 121, 80, 135, 7, 96, 46, 109, 190, 111, 118, 23, 5, 149, 19, 140, 106, 36, 161, 71, 6, 176, 160, 76, 8, 168, 171, 173, 40, 37, 25, 50, 164, 108, 139, 31, 127, 142, 163, 177, 24, 20, 157, 83, 116, 42, 73, 69, 88, 184, 147, 136, 187, 49, 45, 35, 170, 62, 63, 181, 117, 123, 122, 72, 55, 53, 133, 159, 94, 175, 179, 158, 97, 93, 13, 130, 144, 81, 68, 2, 64, 155, 119, 43, 143, 1, 112, 18, 146, 172, 132, 191, 134, 61, 138, 9, 178, 103, 15, 47, 154, 17, 152, 153, 107, 115, 39, 166, 33, 104, 56, 52, 60, 131, 141, 78, 186, 162, 54, 0, 85, 12, 86, 77, 126, 34, 180, 10, 87, 38, 4, 26, 79, 27, 98, 66, 75, 67, 110, 101, 128, 16, 22, 28, 151, 21, 99, 74, 11, 100, 65, 58, 150, 145, 14, 59, 102, 51, 48, 113, 92, 167, 188, 174, 156, 114, 82, 125, 124, 70, 137, 90, 30, 44, 57, 105, 95, 165, 29, 89, 41, 169, 120, 91, 32, 183, 129, 182, 185, 84, the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 4680, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is 1012 3997 5398 5796 21940 23609 25002 28007 32214 33822 38194 1110 4016 5752 10837 15440 15952 17802 27468 32933 33191 35420 95 1953 6554 11381 12839 12880 22901 26742 26910 27621 37825 1146 2232 5658 13131 13785 16771 17466 20561 29400 32962 36879 2023 3420 5107 10789 12303 13316 14428 24912 35363 36348 38787 3283 3637 12474 14376 20459 22584 23093 28876 31485 31742 34849 1807 3890 4865 7562 9091 13778 18361 21934 24548 34267 38260 1613 3620 10165 11464 14071 20675 20803 26814 27593 29483 36485 849 3946 8585 9208 9939 14676 14990 19276 23459 30577 36838 1890 2583 5951 6003 11943 13641 16319 18379 22957 24644 33430 1936 3939 5267 6314 12665 19626 20457 22010 27958 30238 32976 2153 4318 6782 13048 17730 17923 24137 24741 25594 32852 33209 1869 4262 6616 13522 19266 19384 22769 28883 30389 35102 36019 3037 3116 7478 7841 10627 10908 14060 14163 23772 27946 37835 1668 3125 7485 8525 14659 22834 24080 24838 30890 33391 36788 1623 2836 6776 8549 11448 23281 32033 32729 33650 34069 34607 101 1420 5172 7475 11673 18807 21367 23095 26368 30888 37882 3874 3940 4823 16485 21601 21655 21885 25541 30177 31656 35067 592 643 4847 6870 7671 10412 25081 33412 33478 33495 35976 2578 2677 12592 17140 17185 21962 23206 23838 27624 32594 34828 3058 3443 4959 21179 22411 24033 26004 26489 26775 33816 36694 91 2998 10137 11957 12444 22330 24300 26008 26441 26521 38191 889 1840 8881 10228 12495 18162 22259 23385 25687 35853 38848 1332 3031 13482 14262 15897 23112 25954 28035 34898 36286 36991 2505 2599 10980 15245 20084 20114 24496 26309 31139 34090 37258 599 1778 8935 16154 19546 23537 24938 32059 32406 35564 37175 392 1777 4793 8050 10543 10668 14823 25252 32922 36658 37832 1680 2630 7190 7880 10894 20675 27523 33460 33733 34000 35829 532 3750 5075 10603 12466 19838 24231 24998 27647 35111 38617 1786 3066 11367 12452 13896 15346 24646 25509 26109 30358 37392 1027 1659 6483 16919 17636 18905 19741 30579 35934 36515 37617 2064 2354 14085 16460 21378 21719 22981 23329 31701 32057 32640 2009 4421 7595 8790 12803 17649 18527 24246 27584 28757 31794 364 646 9398 13898 17486 17709 20911 31493 31810 32019 33341 2246 3760 4911 19338 25792 27511 28689 30634 31928 34984 36605 3178 3544 8858 9336 9602 12290 16521 27872 28391 28422 36105 1981 2209 12718 20656 21253 22574 28653 29967 33692 36759 37871 787 1545 7652 8376 9628 9995 10289 16260 17606 22673 34564 795 4580 12749 16670 18727 19131 19449 26152 29165 30820 31678 1577 2980 8659 12301 13813 14838 20782 23068 30185 34308 34676 84 434 13572 21777 24581 28397 28490 32547 33282 34655 37579 2927 4440 8979 14992 19009 20435 23558 26280 31320 35106 37704 1974 2712 6552 8585 10051 14848 15186 22968 24285 25878 36054 585 1990 3457 5010 8808 9 2792 4678 22666 32922 342 507 861 18844 32947 554 3395 4094 8147 34616 356 2061 2801 20330 38214 425 2432 4573 7323 28157 73 1192 2618 7812 17947 842 1053 4088 10818 24053 1234 1249 4171 6645 37350 1498 2113 4175 6432 17014 524 2135 2205 6311 7502 191 954 3166 28938 31869 548 586 4101 12129 25819 127 2352 3215 6791 13523 286 4262 4423 14087 38061 1645 3551 4209 14083 15827 719 1087 2813 32857 34499 651 2752 4548 25139 25514 1702 4186 4478 10785 33263 34 3157 4196 5811 36555 643 649 1524 6587 27246 291 836 1036 18936 19201 78 1099 4174 18305 36119 3083 3173 4667 27349 32057 3449 4090 4339 18334 24596 503 3816 4465 29204 35316 102 1693 1799 17180 35877 288 324 1237 16167 33970 224 2831 3571 17861 28530 1202 2803 2834 4943 31485 1112 2196 3027 29308 37101 4242 4291 4503 16344 28769 1020 1927 3349 9686 33845 3179 3304 3891 8448 37247 1076 2319 4512 17010 18781 987 1391 3781 12318 35710 2268 3467 3619 15764 25608 764 1135 2224 8647 17486 2091 4081 4648 8101 33818 471 3668 4069 14925 36242 932 2140 3428 12523 33270 5840 8959 12039 15972 38496 5960 7759 10493 31160 38054 10380 14835 26024 35399 36517 5260 7306 13419 28804 31112 12747 23075 32458 36239 37437 14096 16976 21598 32228 34672 5024 5769 21798 22675 25316 8617 14189 17874 22776 29780 7628 13623 16676 30019 33213 14090 14254 18987 21720 38550 17306 17709 19135 22995 28597 13137 18028 23943 27468 37156 7704 8171 10815 28138
 29526. 6. A reception device comprising a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, wherein the transmission device includes: an encoding unit that performs LDPC encoding on a basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 7/16; a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 148, 189, 3, 121, 80, 135, 7, 96, 46, 109, 190, 111, 118, 23, 5, 149, 19, 140, 106, 36, 161, 71, 6, 176, 160, 76, 8, 168, 171, 173, 40, 37, 25, 50, 164, 108, 139, 31, 127, 142, 163, 177, 24, 20, 157, 83, 116, 42, 73, 69, 88, 184, 147, 136, 187, 49, 45, 35, 170, 62, 63, 181, 117, 123, 122, 72, 55, 53, 133, 159, 94, 175, 179, 158, 97, 93, 13, 130, 144, 81, 68, 2, 64, 155, 119, 43, 143, 1, 112, 18, 146, 172, 132, 191, 134, 61, 138, 9, 178, 103, 15, 47, 154, 17, 152, 153, 107, 115, 39, 166, 33, 104, 56, 52, 60, 131, 141, 78, 186, 162, 54, 0, 85, 12, 86, 77, 126, 34, 180, 10, 87, 38, 4, 26, 79, 27, 98, 66, 75, 67, 110, 101, 128, 16, 22, 28, 151, 21, 99, 74, 11, 100, 65, 58, 150, 145, 14, 59, 102, 51, 48, 113, 92, 167, 188, 174, 156, 114, 82, 125, 124, 70, 137, 90, 30, 44, 57, 105, 95, 165, 29, 89, 41, 169, 120, 91, 32, 183, 129, 182, 185, 84, the check matrix includes: an A matrix of M1 rows and K columns in an upper left of the check matrix, the A matrix being indicated by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of M1 rows and M1 columns, having a staircase structure adjacent to the right of the A matrix; a Z matrix of M1 rows and (N−K−M1) columns, which is a zero matrix adjacent to the right of the B matrix; a C matrix of (N−K−M1) rows and (K+M1) columns adjacent below the A matrix and the B matrix; and a D matrix of (N−K−M1) rows and (N−K−M1) columns, which is a unit matrix adjacent to the right of the C matrix, the predetermined value M1 is 4680, the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the A matrix and the C matrix every 360 columns, and is 1012 3997 5398 5796 21940 23609 25002 28007 32214 33822 38194 1110 4016 5752 10837 15440 15952 17802 27468 32933 33191 35420 95 1953 6554 11381 12839 12880 22901 26742 26910 27621 37825 1146 2232 5658 13131 13785 16771 17466 20561 29400 32962 36879 2023 3420 5107 10789 12303 13316 14428 24912 35363 36348 38787 3283 3637 12474 14376 20459 22584 23093 28876 31485 31742 34849 1807 3890 4865 7562 9091 13778 18361 21934 24548 34267 38260 1613 3620 10165 11464 14071 20675 20803 26814 27593 29483 36485 849 3946 8585 9208 9939 14676 14990 19276 23459 30577 36838 1890 2583 5951 6003 11943 13641 16319 18379 22957 24644 33430 1936 3939 5267 6314 12665 19626 20457 22010 27958 30238 32976 2153 4318 6782 13048 17730 17923 24137 24741 25594 32852 33209 1869 4262 6616 13522 19266 19384 22769 28883 30389 35102 36019 3037 3116 7478 7841 10627 10908 14060 14163 23772 27946 37835 1668 3125 7485 8525 14659 22834 24080 24838 30890 33391 36788 1623 2836 6776 8549 11448 23281 32033 32729 33650 34069 34607 101 1420 5172 7475 11673 18807 21367 23095 26368 30888 37882 3874 3940 4823 16485 21601 21655 21885 25541 30177 31656 35067 592 643 4847 6870 7671 10412 25081 33412 33478 33495 35976 2578 2677 12592 17140 17185 21962 23206 23838 27624 32594 34828 3058 3443 4959 21179 22411 24033 26004 26489 26775 33816 36694 91 2998 10137 11957 12444 22330 24300 26008 26441 26521 38191 889 1840 8881 10228 12495 18162 22259 23385 25687 35853 38848 1332 3031 13482 14262 15897 23112 25954 28035 34898 36286 36991 2505 2599 10980 15245 20084 20114 24496 26309 31139 34090 37258 599 1778 8935 16154 19546 23537 24938 32059 32406 35564 37175 392 1777 4793 8050 10543 10668 14823 25252 32922 36658 37832 1680 2630 7190 7880 10894 20675 27523 33460 33733 34000 35829 532 3750 5075 10603 12466 19838 24231 24998 27647 35111 38617 1786 3066 11367 12452 13896 15346 24646 25509 26109 30358 37392 1027 1659 6483 16919 17636 18905 19741 30579 35934 36515 37617 2064 2354 14085 16460 21378 21719 22981 23329 31701 32057 32640 2009 4421 7595 8790 12803 17649 18527 24246 27584 28757 31794 364 646 9398 13898 17486 17709 20911 31493 31810 32019 33341 2246 3760 4911 19338 25792 27511 28689 30634 31928 34984 36605 3178 3544 8858 9336 9602 12290 16521 27872 28391 28422 36105 1981 2209 12718 20656 21253 22574 28653 29967 33692 36759 37871 787 1545 7652 8376 9628 9995 10289 16260 17606 22673 34564 795 4580 12749 16670 18727 19131 19449 26152 29165 30820 31678 1577 2980 8659 12301 13813 14838 20782 23068 30185 34308 34676 84 434 13572 21777 24581 28397 28490 32547 33282 34655 37579 2927 4440 8979 14992 19009 20435 23558 26280 31320 35106 37704 1974 2712 6552 8585 10051 14848 15186 22968 24285 25878 36054 585 1990 3457 5010 8808 9 2792 4678 22666 32922 342 507 861 18844 32947 554 3395 4094 8147 34616 356 2061 2801 20330 38214 425 2432 4573 7323 28157 73 1192 2618 7812 17947 842 1053 4088 10818 24053 1234 1249 4171 6645 37350 1498 2113 4175 6432 17014 524 2135 2205 6311 7502 191 954 3166 28938 31869 548 586 4101 12129 25819 127 2352 3215 6791 13523 286 4262 4423 14087 38061 1645 3551 4209 14083 15827 719 1087 2813 32857 34499 651 2752 4548 25139 25514 1702 4186 4478 10785 33263 34 3157 4196 5811 36555 643 649 1524 6587 27246 291 836 1036 18936 19201 78 1099 4174 18305 36119 3083 3173 4667 27349 32057 3449 4090 4339 18334 24596 503 3816 4465 29204 35316 102 1693 1799 17180 35877 288 324 1237 16167 33970 224 2831 3571 17861 28530 1202 2803 2834 4943 31485 1112 2196 3027 29308 37101 4242 4291 4503 16344 28769 1020 1927 3349 9686 33845 3179 3304 3891 8448 37247 1076 2319 4512 17010 18781 987 1391 3781 12318 35710 2268 3467 3619 15764 25608 764 1135 2224 8647 17486 2091 4081 4648 8101 33818 471 3668 4069 14925 36242 932 2140 3428 12523 33270 5840 8959 12039 15972 38496 5960 7759 10493 31160 38054 10380 14835 26024 35399 36517 5260 7306 13419 28804 31112 12747 23075 32458 36239 37437 14096 16976 21598 32228 34672 5024 5769 21798 22675 25316 8617 14189 17874 22776 29780 7628 13623 16676 30019 33213 14090 14254 18987 21720 38550 17306 17709 19135 22995 28597 13137 18028 23943 27468 37156 7704 8171 10815 28138
 29526. 7. A transmission method comprising: an encoding step of performing LDPC encoding on a basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 9/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, wherein in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 67, 20, 9, 75, 143, 94, 144, 122, 56, 88, 180, 72, 102, 100, 113, 157, 170, 59, 128, 162, 26, 38, 61, 156, 115, 117, 190, 77, 22, 74, 119, 12, 8, 179, 182, 85, 188, 191, 154, 41, 58, 142, 186, 107, 73, 189, 15, 130, 127, 160, 55, 19, 45, 137, 124, 133, 146, 43, 60, 183, 153, 177, 123, 181, 95, 49, 140, 4, 51, 3, 21, 164, 83, 187, 148, 11, 168, 149, 92, 65, 30, 90, 23, 116, 57, 161, 125, 175, 129, 126, 97, 14, 96, 66, 37, 178, 64, 173, 184, 80, 101, 34, 81, 131, 76, 147, 47, 135, 111, 121, 44, 68, 98, 48, 120, 40, 87, 176, 104, 106, 28, 163, 52, 1, 152, 79, 42, 139, 16, 2, 71, 7, 109, 114, 112, 54, 62, 169, 35, 150, 171, 110, 50, 108, 105, 69, 118, 84, 39, 132, 63, 31, 18, 134, 103, 185, 6, 145, 24, 70, 36, 29, 5, 93, 99, 33, 82, 89, 167, 174, 27, 165, 91, 138, 155, 32, 159, 141, 136, 151, 25, 158, 86, 17, 13, 172, 53, 10, 46, 166, 0, 78, the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is 110 3064 6740 7801 10228 13445 17599 17891 17979 18044 19923 21848 23262 25585 25968 30124 1578 8914 9141 9731 10605 11690 12824 18127 18458 24648 24950 25150 26323 26514 27385 27460 3054 3640 3923 7332 10770 12215 14455 14849 15619 20870 22033 26427 28067 28560 29777 29780 1348 4248 5479 8902 9101 9356 10581 11614 12813 21554 22985 23701 24099 24575 24786 27370 3266 8358 16544 16689 16693 16823 17565 18543 19229 21121 23799 24981 25423 28997 29808 30202 320 1198 1549 5407 6080 8542 9352 12418 13391 14736 15012 18328 19398 23391 28117 28793 2114 3294 3770 5225 5556 5991 7075 7889 11145 11386 16561 18956 19034 23605 26085 27132 3623 4011 4225 5249 5489 5711 7240 9831 10458 14697 15420 16015 17782 23244 24215 24386 2624 2750 3871 8247 11135 13702 19290 22209 22975 23811 23931 24872 25154 25165 28375 30200 1060 1240 2040 2382 7723 9165 9656 10398 14517 16653 21241 22348 23476 27203 28443 28445 1070 1233 3416 6633 11736 12808 15454 16505 18720 20162 21425 21874 26069 26855 27292 27978 420 5524 10279 11218 12500 12913 15389 15824 19414 19588 21138 23846 26621 27907 28594 28781 151 1356 2323 3289 4501 10573 13667 14642 16127 17040 17475 18055 24061 26204 26567 29277 1410 3656 4080 6963 8834 10527 17490 17584 18065 19234 22211 22338 23746 24662 29863 30227 1924 2694 3285 8761 9693 11005 17592 21259 21322 21546 21555 24044 24173 26988 27640 28506 1069 6483 6554 9027 11655 12453 16595 17877 18350 18995 21304 21442 23836 25468 28820 29453 149 1621 2199 3141 8403 11974 14969 16197 18844 21027 21921 22266 22399 22691 25727 27721 3689 4839 7971 8419 10500 12308 13435 14487 16502 16622 17229 17468 22710 23904 25074 28508 1270 7007 9830 12698 14204 16075 17613 19391 21362 21726 21816 23014 23651 26419 26748 27195 96 1953 2456 2712 2809 3196 5939 10634 21828 24606 26169 26801 27391 28578 29725 30142 832 3394 4145 5375 6199 7122 7405 7706 10136 10792 15058 15860 21881 23908 25174 25837 730 1735 2917 4106 5004 5849 8194 8943 9136 17599 18456 20191 22798 27935 29559 6238 6776 6799 9142 11199 11867 15979 16830 18110 18396 21897 22590 24020 29578 29644 407 2138 4493 7979 8225 9467 11956 12940 15566 15809 16058 18211 22073 28314 28713 957 1552 1869 4388 7642 7904 13408 13453 16431 19327 21444 22188 25719 28511 29192 3617 8663 22378 28704 8598 12647 19278 22416 15176 16377 16644 22732 12463 12711 18341 11079 13446 29071 2446 4068 8542 10838 11660 27428 16403 21750 23199 9181 16572 18381 7227 18770 21858 7379 9316 16247 8923 14861 29618 6531 24652 26817 5564 8875 18025 8019 14642 21169 16683 17257 29298 4078 6023 8853 13942 15217 15501 7484 8302 27199 671 14966 20886 1240 11897 14925 12800 25474 28603 3576 5308 11168 13430 15265 18232 3439 5544 21849 3257 16996 23750 1865 14153 22669 7640 15098 17364 6137 19401 24836 5986 9035 11444 4799 20865 29150 8360 23554 29246 2002 18215 22258 9679 11951 26583 2844 12330 18156 3744 6949 14754 8262 10288 27142 1087 16563 22815 1328 13273 21749 2092 9191 28045 3250 10549 18252 13975 15172 17135 2520 26310 28787 4395 8961 26753 6413 15437 19520 5809 10936 17089 1670 13574 25125 5865 6175 21175 8391 11680 22660 5485 11743 15165 21021 21798 30209 12519 13402 26300 3472 25935 26412 3377 7398 28867 2430 24650 29426 3364 13409 22914 6838 13491 16229 18393 20764 28078 289 20279 24906 4732 6162 13569 8993 17053 29387 2210 5024 24030 21 22976 24053 12359 15499 28251 4640 11480 24391 1083 7965 16573 13116 23916 24421 10129 16284 23855 1758 3843 21163 5626 13543 26708 14918 17713 21718 13556 20450 24679 3911 16778 29952 11735 13710 22611 5347 21681 22906 6912 12045 15866 713 15429 23281 7133 17440 28982 12355 17564 28059 7658 11158 29885 17610 18755 28852 7680 16212 30111 8812 10144
 15718. 8. A reception device comprising a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, wherein the transmission device includes: an encoding unit that performs LDPC encoding on a basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 9/16, a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 67, 20, 9, 75, 143, 94, 144, 122, 56, 88, 180, 72, 102, 100, 113, 157, 170, 59, 128, 162, 26, 38, 61, 156, 115, 117, 190, 77, 22, 74, 119, 12, 8, 179, 182, 85, 188, 191, 154, 41, 58, 142, 186, 107, 73, 189, 15, 130, 127, 160, 55, 19, 45, 137, 124, 133, 146, 43, 60, 183, 153, 177, 123, 181, 95, 49, 140, 4, 51, 3, 21, 164, 83, 187, 148, 11, 168, 149, 92, 65, 30, 90, 23, 116, 57, 161, 125, 175, 129, 126, 97, 14, 96, 66, 37, 178, 64, 173, 184, 80, 101, 34, 81, 131, 76, 147, 47, 135, 111, 121, 44, 68, 98, 48, 120, 40, 87, 176, 104, 106, 28, 163, 52, 1, 152, 79, 42, 139, 16, 2, 71, 7, 109, 114, 112, 54, 62, 169, 35, 150, 171, 110, 50, 108, 105, 69, 118, 84, 39, 132, 63, 31, 18, 134, 103, 185, 6, 145, 24, 70, 36, 29, 5, 93, 99, 33, 82, 89, 167, 174, 27, 165, 91, 138, 155, 32, 159, 141, 136, 151, 25, 158, 86, 17, 13, 172, 53, 10, 46, 166, 0, 78, the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is 110 3064 6740 7801 10228 13445 17599 17891 17979 18044 19923 21848 23262 25585 25968 30124 1578 8914 9141 9731 10605 11690 12824 18127 18458 24648 24950 25150 26323 26514 27385 27460 3054 3640 3923 7332 10770 12215 14455 14849 15619 20870 22033 26427 28067 28560 29777 29780 1348 4248 5479 8902 9101 9356 10581 11614 12813 21554 22985 23701 24099 24575 24786 27370 3266 8358 16544 16689 16693 16823 17565 18543 19229 21121 23799 24981 25423 28997 29808 30202 320 1198 1549 5407 6080 8542 9352 12418 13391 14736 15012 18328 19398 23391 28117 28793 2114 3294 3770 5225 5556 5991 7075 7889 11145 11386 16561 18956 19034 23605 26085 27132 3623 4011 4225 5249 5489 5711 7240 9831 10458 14697 15420 16015 17782 23244 24215 24386 2624 2750 3871 8247 11135 13702 19290 22209 22975 23811 23931 24872 25154 25165 28375 30200 1060 1240 2040 2382 7723 9165 9656 10398 14517 16653 21241 22348 23476 27203 28443 28445 1070 1233 3416 6633 11736 12808 15454 16505 18720 20162 21425 21874 26069 26855 27292 27978 420 5524 10279 11218 12500 12913 15389 15824 19414 19588 21138 23846 26621 27907 28594 28781 151 1356 2323 3289 4501 10573 13667 14642 16127 17040 17475 18055 24061 26204 26567 29277 1410 3656 4080 6963 8834 10527 17490 17584 18065 19234 22211 22338 23746 24662 29863 30227 1924 2694 3285 8761 9693 11005 17592 21259 21322 21546 21555 24044 24173 26988 27640 28506 1069 6483 6554 9027 11655 12453 16595 17877 18350 18995 21304 21442 23836 25468 28820 29453 149 1621 2199 3141 8403 11974 14969 16197 18844 21027 21921 22266 22399 22691 25727 27721 3689 4839 7971 8419 10500 12308 13435 14487 16502 16622 17229 17468 22710 23904 25074 28508 1270 7007 9830 12698 14204 16075 17613 19391 21362 21726 21816 23014 23651 26419 26748 27195 96 1953 2456 2712 2809 3196 5939 10634 21828 24606 26169 26801 27391 28578 29725 30142 832 3394 4145 5375 6199 7122 7405 7706 10136 10792 15058 15860 21881 23908 25174 25837 730 1735 2917 4106 5004 5849 8194 8943 9136 17599 18456 20191 22798 27935 29559 6238 6776 6799 9142 11199 11867 15979 16830 18110 18396 21897 22590 24020 29578 29644 407 2138 4493 7979 8225 9467 11956 12940 15566 15809 16058 18211 22073 28314 28713 957 1552 1869 4388 7642 7904 13408 13453 16431 19327 21444 22188 25719 28511 29192 3617 8663 22378 28704 8598 12647 19278 22416 15176 16377 16644 22732 12463 12711 18341 11079 13446 29071 2446 4068 8542 10838 11660 27428 16403 21750 23199 9181 16572 18381 7227 18770 21858 7379 9316 16247 8923 14861 29618 6531 24652 26817 5564 8875 18025 8019 14642 21169 16683 17257 29298 4078 6023 8853 13942 15217 15501 7484 8302 27199 671 14966 20886 1240 11897 14925 12800 25474 28603 3576 5308 11168 13430 15265 18232 3439 5544 21849 3257 16996 23750 1865 14153 22669 7640 15098 17364 6137 19401 24836 5986 9035 11444 4799 20865 29150 8360 23554 29246 2002 18215 22258 9679 11951 26583 2844 12330 18156 3744 6949 14754 8262 10288 27142 1087 16563 22815 1328 13273 21749 2092 9191 28045 3250 10549 18252 13975 15172 17135 2520 26310 28787 4395 8961 26753 6413 15437 19520 5809 10936 17089 1670 13574 25125 5865 6175 21175 8391 11680 22660 5485 11743 15165 21021 21798 30209 12519 13402 26300 3472 25935 26412 3377 7398 28867 2430 24650 29426 3364 13409 22914 6838 13491 16229 18393 20764 28078 289 20279 24906 4732 6162 13569 8993 17053 29387 2210 5024 24030 21 22976 24053 12359 15499 28251 4640 11480 24391 1083 7965 16573 13116 23916 24421 10129 16284 23855 1758 3843 21163 5626 13543 26708 14918 17713 21718 13556 20450 24679 3911 16778 29952 11735 13710 22611 5347 21681 22906 6912 12045 15866 713 15429 23281 7133 17440 28982 12355 17564 28059 7658 11158 29885 17610 18755 28852 7680 16212 30111 8812 10144
 15718. 9. A transmission method comprising: an encoding step of performing LDPC encoding on a basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 11/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, wherein in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 84, 126, 45, 76, 121, 91, 52, 162, 79, 187, 134, 108, 47, 16, 72, 119, 43, 107, 98, 135, 147, 110, 0, 60, 4, 61, 117, 24, 167, 65, 40, 55, 73, 112, 85, 35, 156, 95, 137, 171, 9, 11, 54, 131, 138, 157, 152, 111, 183, 161, 41, 69, 21, 94, 113, 8, 153, 39, 57, 143, 86, 12, 188, 184, 15, 30, 118, 136, 64, 169, 148, 22, 6, 68, 168, 78, 105, 101, 190, 3, 59, 124, 170, 62, 87, 46, 28, 29, 186, 2, 25, 177, 140, 53, 154, 37, 18, 189, 93, 114, 33, 1, 158, 122, 103, 5, 104, 80, 166, 34, 106, 51, 10, 180, 139, 125, 178, 100, 13, 70, 142, 185, 159, 50, 66, 102, 150, 127, 160, 92, 81, 173, 115, 144, 145, 128, 74, 88, 20, 116, 179, 96, 17, 155, 175, 75, 165, 7, 191, 149, 44, 23, 99, 48, 163, 42, 63, 164, 90, 120, 27, 31, 14, 19, 32, 174, 26, 67, 89, 97, 56, 146, 82, 133, 129, 109, 71, 58, 130, 182, 123, 176, 49, 36, 181, 38, 141, 151, 83, 77, 172, 132, the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is 983 2226 4091 5418 5824 6483 6914 8239 8364 10220 10322 15658 16928 17307 18061 1584 5655 6787 7213 7270 8585 8995 9294 9832 9982 11185 12221 12889 17573 19096 319 1077 1796 2421 6574 11763 13465 14527 15147 15218 16000 18284 20199 21095 21194 767 1018 3780 3826 4288 4855 7169 7431 9151 10097 10919 12050 13261 19816 20932 173 692 3552 5046 6523 6784 9542 10482 14658 14663 15168 16153 16410 17546 20989 2214 2286 2445 2856 3562 3615 3970 6065 7117 7989 8180 15971 20253 21312 21428 532 1361 1905 3577 5147 10409 11348 11660 15230 17283 18724 20190 20542 21159 21282 3242 5061 7587 7677 8614 8834 9130 9135 9331 13480 13544 14263 15438 20548 21174 1507 4159 4946 5215 5653 6385 7131 8049 10198 10499 12215 14105 16118 17016 21371 212 1856 1981 2056 6766 8123 10128 10957 11159 11237 12893 14064 17760 18933 19009 329 5552 5948 6484 10108 10127 10816 13210 14985 15110 15565 15969 17136 18504 20818 4753 5744 6511 7062 7355 8379 8817 13503 13650 14014 15393 15640 18127 18595 20426 1152 1707 4013 5932 8540 9077 11521 11923 11954 12529 13519 15641 16262 17874 19386 858 2355 2511 3125 5531 6472 8146 11423 11558 11760 13556 15194 20782 20988 21261 216 1722 2750 3809 6210 8233 9183 10734 11339 12321 12898 15902 17437 19085 21588 1560 1718 1757 2292 2349 3992 6943 7369 7806 10282 11373 13624 14608 17087 18011 1375 1640 2015 2539 2691 2967 4344 7125 9176 9435 12378 12520 12901 15704 18897 1703 2861 2986 3574 7208 8486 9412 9879 13027 13945 14873 15546 16516 18931 21070 309 1587 3118 5472 10035 13988 15019 15322 16373 17580 17728 18125 18872 19876 20457 984 991 1203 3159 4303 5734 8850 9626 12217 17227 17269 18695 18854 19580 19684 2429 6165 6828 7761 9761 9899 9942 10151 11198 11271 13184 14026 14560 18962 20570 876 1074 5177 5185 6415 6451 10856 11603 14590 14658 16293 17221 19273 19319 20447 557 607 2473 5002 6601 9876 10284 10809 13563 14849 15710 16798 17509 18927 21306 939 1271 3085 5054 5723 5959 7530 10912 13375 16696 18753 19673 20328 21068 21258 2802 3312 5015 6041 6943 7606 9375 12116 12868 12964 13374 13594 14978 16125 18621 3002 6512 6965 6967 8504 10777 11217 11931 12647 12686 12740 12900 12958 13870 17860 151 3874 4228 7837 10244 10589 14530 15323 16462 17711 18995 19363 19376 19540 20641 1249 2946 2959 3330 4264 7797 10652 11845 12987 15974 16536 17520 19851 20150 20172 4769 11033 14937 1431 2870 15158 9416 14905 20800 1708 9944 16952 1116 1179 20743 3665 8987 16223 655 11424 17411 42 2717 11613 2787 9015 15081 3718 7305 11822 18306 18499 18843 1208 4586 10578 9494 12676 13710 10580 15127 20614 4439 15646 19861 5255 12337 14649 2532 7552 10813 1591 7781 13020 7264 8634 17208 7462 10069 17710 1320 3382 6439 4057 9762 11401 1618 7604 19881 3858 16826 17768 6158 11759 19274 3767 11872 15137 2111 5563 16776 1888 15452 17925 2840 15375 16376 3695 11232 16970 10181 16329 17920 9743 13974 17724 29 16450 20509 2393 17877 19591 1827 15175 15366 3771 14716 18363 5585 14762 19813 7186 8104 12067 2554 12025 15873 2208 5739 6150 2816 12745 17143 9363 11582 17976 5834 8178 12517 3546 15667 19511 5211 10685 20833 3399 7774 16435 3767 4542 8775 4404 6349 19426 4812 11088 16761 5761 11289 17985 9989 11488 15986 10200 16710 20899 6970 12774 20558 1304 2495 3507 5236 7678 10437 4493 10472 19880 1883 14768 21100 352 18797 20570 1411 3221 4379 3304 11013 18382 14864 16951 18782 2887 15658 17633 7109 7383 19956 4293 12990 13934 9890 15206 15786 2987 5455 8787 5782 7137 15981 736 1961 10441 2728 11808 21305 4663 4693 13680 1965 3668 9025 818 10532 16332 7006 16717 21102 2955 15500 20140 8274 13451 19436 3604 13158 21154 5519 6531 9995 1629 17919 18532 15199 16690 16884 5177 5869 14843 5 5088 19940 16910 20686 21206 10662 11610 17578 3378 4579 12849 5947 19300 19762 2545 10686 12579 4568 10814 19032 677 18652 18992 190 11377 12987 4183 6801 20025 6944 8321 15868 3311 6049 14757 7155 11435 16353 4778 5674 15973 1889 3361 7563 467 5999 10103 7613 11096 19536 2244 4442 6000 9055 13516 15414 4831 6111 10744 3792 8258 15106 6990 9168 17589 7920 11548 20786 10533 14361
 19577. 10. A reception device comprising a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, wherein the transmission device includes: an encoding unit that performs LDPC encoding on a basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 11/16; a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 84, 126, 45, 76, 121, 91, 52, 162, 79, 187, 134, 108, 47, 16, 72, 119, 43, 107, 98, 135, 147, 110, 0, 60, 4, 61, 117, 24, 167, 65, 40, 55, 73, 112, 85, 35, 156, 95, 137, 171, 9, 11, 54, 131, 138, 157, 152, 111, 183, 161, 41, 69, 21, 94, 113, 8, 153, 39, 57, 143, 86, 12, 188, 184, 15, 30, 118, 136, 64, 169, 148, 22, 6, 68, 168, 78, 105, 101, 190, 3, 59, 124, 170, 62, 87, 46, 28, 29, 186, 2, 25, 177, 140, 53, 154, 37, 18, 189, 93, 114, 33, 1, 158, 122, 103, 5, 104, 80, 166, 34, 106, 51, 10, 180, 139, 125, 178, 100, 13, 70, 142, 185, 159, 50, 66, 102, 150, 127, 160, 92, 81, 173, 115, 144, 145, 128, 74, 88, 20, 116, 179, 96, 17, 155, 175, 75, 165, 7, 191, 149, 44, 23, 99, 48, 163, 42, 63, 164, 90, 120, 27, 31, 14, 19, 32, 174, 26, 67, 89, 97, 56, 146, 82, 133, 129, 109, 71, 58, 130, 182, 123, 176, 49, 36, 181, 38, 141, 151, 83, 77, 172, 132, the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is 983 2226 4091 5418 5824 6483 6914 8239 8364 10220 10322 15658 16928 17307 18061 1584 5655 6787 7213 7270 8585 8995 9294 9832 9982 11185 12221 12889 17573 19096 319 1077 1796 2421 6574 11763 13465 14527 15147 15218 16000 18284 20199 21095 21194 767 1018 3780 3826 4288 4855 7169 7431 9151 10097 10919 12050 13261 19816 20932 173 692 3552 5046 6523 6784 9542 10482 14658 14663 15168 16153 16410 17546 20989 2214 2286 2445 2856 3562 3615 3970 6065 7117 7989 8180 15971 20253 21312 21428 532 1361 1905 3577 5147 10409 11348 11660 15230 17283 18724 20190 20542 21159 21282 3242 5061 7587 7677 8614 8834 9130 9135 9331 13480 13544 14263 15438 20548 21174 1507 4159 4946 5215 5653 6385 7131 8049 10198 10499 12215 14105 16118 17016 21371 212 1856 1981 2056 6766 8123 10128 10957 11159 11237 12893 14064 17760 18933 19009 329 5552 5948 6484 10108 10127 10816 13210 14985 15110 15565 15969 17136 18504 20818 4753 5744 6511 7062 7355 8379 8817 13503 13650 14014 15393 15640 18127 18595 20426 1152 1707 4013 5932 8540 9077 11521 11923 11954 12529 13519 15641 16262 17874 19386 858 2355 2511 3125 5531 6472 8146 11423 11558 11760 13556 15194 20782 20988 21261 216 1722 2750 3809 6210 8233 9183 10734 11339 12321 12898 15902 17437 19085 21588 1560 1718 1757 2292 2349 3992 6943 7369 7806 10282 11373 13624 14608 17087 18011 1375 1640 2015 2539 2691 2967 4344 7125 9176 9435 12378 12520 12901 15704 18897 1703 2861 2986 3574 7208 8486 9412 9879 13027 13945 14873 15546 16516 18931 21070 309 1587 3118 5472 10035 13988 15019 15322 16373 17580 17728 18125 18872 19876 20457 984 991 1203 3159 4303 5734 8850 9626 12217 17227 17269 18695 18854 19580 19684 2429 6165 6828 7761 9761 9899 9942 10151 11198 11271 13184 14026 14560 18962 20570 876 1074 5177 5185 6415 6451 10856 11603 14590 14658 16293 17221 19273 19319 20447 557 607 2473 5002 6601 9876 10284 10809 13563 14849 15710 16798 17509 18927 21306 939 1271 3085 5054 5723 5959 7530 10912 13375 16696 18753 19673 20328 21068 21258 2802 3312 5015 6041 6943 7606 9375 12116 12868 12964 13374 13594 14978 16125 18621 3002 6512 6965 6967 8504 10777 11217 11931 12647 12686 12740 12900 12958 13870 17860 151 3874 4228 7837 10244 10589 14530 15323 16462 17711 18995 19363 19376 19540 20641 1249 2946 2959 3330 4264 7797 10652 11845 12987 15974 16536 17520 19851 20150 20172 4769 11033 14937 1431 2870 15158 9416 14905 20800 1708 9944 16952 1116 1179 20743 3665 8987 16223 655 11424 17411 42 2717 11613 2787 9015 15081 3718 7305 11822 18306 18499 18843 1208 4586 10578 9494 12676 13710 10580 15127 20614 4439 15646 19861 5255 12337 14649 2532 7552 10813 1591 7781 13020 7264 8634 17208 7462 10069 17710 1320 3382 6439 4057 9762 11401 1618 7604 19881 3858 16826 17768 6158 11759 19274 3767 11872 15137 2111 5563 16776 1888 15452 17925 2840 15375 16376 3695 11232 16970 10181 16329 17920 9743 13974 17724 29 16450 20509 2393 17877 19591 1827 15175 15366 3771 14716 18363 5585 14762 19813 7186 8104 12067 2554 12025 15873 2208 5739 6150 2816 12745 17143 9363 11582 17976 5834 8178 12517 3546 15667 19511 5211 10685 20833 3399 7774 16435 3767 4542 8775 4404 6349 19426 4812 11088 16761 5761 11289 17985 9989 11488 15986 10200 16710 20899 6970 12774 20558 1304 2495 3507 5236 7678 10437 4493 10472 19880 1883 14768 21100 352 18797 20570 1411 3221 4379 3304 11013 18382 14864 16951 18782 2887 15658 17633 7109 7383 19956 4293 12990 13934 9890 15206 15786 2987 5455 8787 5782 7137 15981 736 1961 10441 2728 11808 21305 4663 4693 13680 1965 3668 9025 818 10532 16332 7006 16717 21102 2955 15500 20140 8274 13451 19436 3604 13158 21154 5519 6531 9995 1629 17919 18532 15199 16690 16884 5177 5869 14843 5 5088 19940 16910 20686 21206 10662 11610 17578 3378 4579 12849 5947 19300 19762 2545 10686 12579 4568 10814 19032 677 18652 18992 190 11377 12987 4183 6801 20025 6944 8321 15868 3311 6049 14757 7155 11435 16353 4778 5674 15973 1889 3361 7563 467 5999 10103 7613 11096 19536 2244 4442 6000 9055 13516 15414 4831 6111 10744 3792 8258 15106 6990 9168 17589 7920 11548 20786 10533 14361
 19577. 11. A transmission method comprising: an encoding step of performing LDPC encoding on a basis of a check matrix of an LDPC code with a code length N of 69120 bits and an encoding rate r of 13/16; a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping step of mapping the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, wherein in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 30, 127, 60, 115, 80, 50, 150, 39, 176, 171, 47, 104, 70, 33, 56, 3, 10, 26, 19, 149, 153, 141, 98, 46, 64, 71, 130, 107, 94, 16, 164, 169, 57, 168, 126, 157, 133, 12, 154, 135, 35, 53, 40, 183, 28, 1, 160, 67, 163, 134, 181, 59, 99, 186, 86, 36, 178, 152, 48, 117, 44, 14, 66, 172, 17, 31, 182, 166, 187, 55, 62, 143, 69, 77, 9, 113, 158, 91, 189, 84, 151, 74, 45, 97, 122, 114, 75, 41, 162, 90, 110, 106, 116, 131, 129, 188, 92, 11, 147, 108, 20, 159, 146, 51, 29, 109, 89, 6, 96, 155, 43, 111, 138, 85, 119, 5, 22, 105, 170, 4, 15, 148, 145, 63, 0, 156, 81, 68, 13, 137, 79, 103, 2, 179, 38, 180, 132, 123, 144, 167, 140, 174, 49, 37, 82, 128, 101, 21, 124, 177, 121, 8, 23, 136, 42, 27, 139, 72, 185, 18, 65, 161, 7, 125, 88, 34, 73, 184, 52, 190, 120, 102, 100, 87, 95, 118, 83, 112, 175, 78, 58, 24, 165, 54, 61, 25, 191, 76, 142, 93, 173, 32, the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is 1031 4123 6253 6610 8007 8656 9181 9404 9596 11501 11654 11710 11994 12177 399 553 1442 2820 4402 4823 5011 5493 7070 8340 8500 9054 11201 11387 201 607 1428 2354 5358 5524 6617 6785 7708 10220 11970 12268 12339 12537 36 992 1930 4525 5837 6283 6887 7284 7489 7550 10329 11202 11399 12795 589 1564 1747 2960 3833 4502 7491 7746 8196 9567 9574 10187 10591 12947 804 1177 1414 3765 4745 7594 9126 9230 9251 10299 10336 11563 11844 12209 2774 2830 3918 4148 4963 5356 7125 7645 7868 8137 9119 9189 9206 12363 59 448 947 3622 5139 8115 9364 9548 9609 9750 10212 10937 11044 12668 715 1352 4538 5277 5729 6210 6418 6938 7090 7109 7386 9012 10737 11893 1583 2059 3398 3619 4277 6896 7484 7525 8284 9318 9817 10227 11636 12204 53 549 3010 5441 6090 9175 9336 9358 9839 10117 11307 11467 11507 12902 861 1054 1177 1201 1383 2538 4563 6451 6800 10540 11222 11757 12240 12732 330 1450 1798 2301 2652 3038 3187 3277 4324 4610 9395 10240 10796 11100 316 751 1226 1746 2124 2505 3497 3833 3891 7551 8696 9763 11978 12661 2677 2888 2904 3923 4804 5105 6855 7222 7893 7907 9674 10274 12683 12702 173 3397 3520 5131 5560 6666 6783 6893 7742 7842 9364 9442 12287 421 943 1893 1920 3273 4052 5758 5787 7043 11051 12141 12209 12500 679 792 2543 3243 3385 3576 4190 7501 8233 8302 9212 9522 12286 911 3651 4023 4462 4650 5336 5762 6506 8050 8381 9636 9724 12486 1373 1728 1911 4101 4913 5003 6859 7137 8035 9056 9378 9937 10184 515 2357 2779 2797 3163 3845 3976 6969 7704 9104 10102 11507 12700 270 1744 1804 3432 3782 4643 5946 6279 6549 7064 7393 11659 12002 261 1517 2269 3554 4762 5103 5460 6429 6464 8962 9651 10927 12268 782 1217 1395 2383 5754 6060 6540 7109 7286 7438 7846 9488 10119 2070 2247 2589 2644 3270 3875 4901 6475 8953 10090 10629 12496 12547 863 1190 1609 2971 3564 4148 5123 5262 6301 7797 7804 9517 11408 449 488 865 3549 3939 4410 4500 5700 7120 8778 9223 11660 12021 1107 1408 1883 2752 3818 4714 5979 6485 7314 7821 11290 11472 12325 713 2492 2507 2641 3576 4711 5021 5831 7334 8362 9094 9690 10778 1487 2344 5035 5336 5727 6495 9009 9345 11090 11261 11314 12383 12944 1038 1463 1472 2944 3202 5742 5793 6972 7853 8919 9808 10549 12619 134 957 2018 2140 2629 3884 5821 7319 8676 10305 10670 12031 12588 5294 9842 4396 6648 2863 5308 10467 11711 3412 6909 450 3919 5639 9801 298 4323 397 10223 4424 9051 2038 2376 5889 11321 12500 3590 4081 12684 3485 4016 9826 6 2869 8310 5983 9818 10877 2282 9346 11477 4931 6135 10473 300 2901 9937 3185 5215 7479 472 5845 5915 2476 7687 11934 3279 8782 11527 4350 7138 7144 7454 7818 8253 1391 8717 8844 1940 4736 10556 5471 7344 8089 9157 10640 11919 1343 5402 12724 2581 4118 8142 5165 9328 11386 7222 7262 12955 6711 11224 11737 401 3195 11940 6114 6969 8208 1402 7917 9738 965 7700 10139 3428 5767 12000 3501 7052 8803 1447 10504 10961 1870 1914 7762 613 2063 10520 3561 6480 10466 3389 3887 10110 995 1104 1640 1492 4122 7572 3243 9765 12415 7297 11200 11533 1959 10325 11306 1675 5313 11475 3621 4658 12790 4208 5650 8687 2467 7691 11886 3039 3190 5017 866 1375 2272 4374 6453 8228 2763 4668 4749 640 1346 6924 6588 6983 10075 3389 9260 12508 89 5799 9973 1290 2978 8038 317 742 8017 5378 5618 6586 3369 3827 4536 1000 10436 12288 3762 11384 11897 848 874 8968 1001 4751 12066 1788 6685 12397 5721 8247 9005 649 7547 9837 2263 9415 10862 3954 4111 7767 952 4393 5523 8132 8580 10906 4191 9677 12585 1071 10601 11106 3069 6943 11015 5555 8088 9537 85 2810 3100 1249 8418 8684 2743 12099 12686 2908 3691 9890 10172 10409 11615 8358 10584 12082 4902 6310 8368 4976 10047 11299 7325 8228 11092 4942 6974 8533 5782 9780 9869 15 4728 10395 369 1900 11517 3796 7434 9085 2473 9813 12636 1472 3557 6607 174 3715 4811 6263 6694 8114 4538 6635 9101 3199 8348 10057 6176 7498 7937 1837 3382 5688 8897 11342 11680 455 6465 7428 1900 3666 8968 3481 6308 10199 159 2654 12150 5602 6695 12897 3309 4899 6415 6 99 7615 1722 6386 11112 5090 8873 10718 4164 6731 12121 367 846 7678 222 6050 12711 3154 7149 7557 1556 4667 7990 2536 9712 9932 4104 7040 9983 6365 11604 12457 3393 10323 10743 724 2237 5455 108 1705
 6151. 12. A reception device comprising a group-wise deinterleaving unit that returns an arrangement of an LDPC code after group-wise interleaving which is obtained from data transmitted from a transmission device to an original arrangement, wherein the transmission device includes: an encoding unit that performs LDPC encoding on a basis of a check matrix of the LDPC code with a code length N of 69120 bits and an encoding rate r of 13/16; a group-wise interleaving unit that performs group-wise interleaving of interleaving the LDPC code in units of bit groups of 360 bits; and a mapping unit that maps the LDPC code in any one of 1024 signal points of 1D-non-uniform constellation (NUC) of 1024QAM in units of 10 bits, in the group-wise interleaving, the (i+1)-th bit group from a lead of the LDPC code is set as a bit group i, and an arrangement of bit groups 0 to 191 of the 69120-bit LDPC code is interleaved into an arrangement of a bit group 30, 127, 60, 115, 80, 50, 150, 39, 176, 171, 47, 104, 70, 33, 56, 3, 10, 26, 19, 149, 153, 141, 98, 46, 64, 71, 130, 107, 94, 16, 164, 169, 57, 168, 126, 157, 133, 12, 154, 135, 35, 53, 40, 183, 28, 1, 160, 67, 163, 134, 181, 59, 99, 186, 86, 36, 178, 152, 48, 117, 44, 14, 66, 172, 17, 31, 182, 166, 187, 55, 62, 143, 69, 77, 9, 113, 158, 91, 189, 84, 151, 74, 45, 97, 122, 114, 75, 41, 162, 90, 110, 106, 116, 131, 129, 188, 92, 11, 147, 108, 20, 159, 146, 51, 29, 109, 89, 6, 96, 155, 43, 111, 138, 85, 119, 5, 22, 105, 170, 4, 15, 148, 145, 63, 0, 156, 81, 68, 13, 137, 79, 103, 2, 179, 38, 180, 132, 123, 144, 167, 140, 174, 49, 37, 82, 128, 101, 21, 124, 177, 121, 8, 23, 136, 42, 27, 139, 72, 185, 18, 65, 161, 7, 125, 88, 34, 73, 184, 52, 190, 120, 102, 100, 87, 95, 118, 83, 112, 175, 78, 58, 24, 165, 54, 61, 25, 191, 76, 142, 93, 173, 32, the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing positions of elements of 1's of the information matrix portion every 360 columns, and is 1031 4123 6253 6610 8007 8656 9181 9404 9596 11501 11654 11710 11994 12177 399 553 1442 2820 4402 4823 5011 5493 7070 8340 8500 9054 11201 11387 201 607 1428 2354 5358 5524 6617 6785 7708 10220 11970 12268 12339 12537 36 992 1930 4525 5837 6283 6887 7284 7489 7550 10329 11202 11399 12795 589 1564 1747 2960 3833 4502 7491 7746 8196 9567 9574 10187 10591 12947 804 1177 1414 3765 4745 7594 9126 9230 9251 10299 10336 11563 11844 12209 2774 2830 3918 4148 4963 5356 7125 7645 7868 8137 9119 9189 9206 12363 59 448 947 3622 5139 8115 9364 9548 9609 9750 10212 10937 11044 12668 715 1352 4538 5277 5729 6210 6418 6938 7090 7109 7386 9012 10737 11893 1583 2059 3398 3619 4277 6896 7484 7525 8284 9318 9817 10227 11636 12204 53 549 3010 5441 6090 9175 9336 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